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Article

Global Prevalence Estimates of Toxascaris leonina Infection in Dogs and Cats

1
Infectious Diseases and Tropical Medicine Research Center, Health Research Institute, Babol University of Medical Sciences, Babol, Iran
2
Department of Epidemiology and Biostatistics, Faculty of Health, Cardiovascular Diseases Research Center, Birjand University of Medical Sciences, Birjand, Iran
3
Cellular and Molecular Biology Research Center, Shahid Beheshti University of Medical Sciences, Tehran, Iran
4
Department of Veterinary Biosciences, Melbourne Veterinary School, Faculty of Veterinary and Agricultural Sciences, University of Melbourne, Parkville, VIC, Australia
5
Innovative Medical Research Center, Department of Medical Parasitology and Mycology, School of Medicine, Mashhad Branch, Islamic Azad University, Mashhad, Iran
6
Department of Parasitology, Abadan Faculty of Medical Sciences, Abadan, Iran
7
Food Health Research Center, Department of Environmental Health Engineering, Hormozgan University of Medical Sciences, Bandar Abbas, Iran
8
School of Graduate Studies, School of Veterinary Medicine, St. George’s University, WINDREF, Grenada, West Indies
*
Authors to whom correspondence should be addressed.
Submission received: 1 June 2020 / Revised: 16 June 2020 / Accepted: 17 June 2020 / Published: 23 June 2020
(This article belongs to the Special Issue Animal Parasitic Diseases)

Abstract

:
Toxascaris leonina is an ascaridoid nematode of dogs and cats; this parasite affects the health of these animals. This study estimated the global prevalence of Ta. leonina infection in dogs and cats using random effects meta-analysis as well as subgroup, meta-regression and heterogeneity analyses. The data were stratified according to geographical region, the type of dogs and cats and environmental variables. A quantitative analysis of 135 published studies, involving 119,317 dogs and 25,364 cats, estimated prevalence rates of Ta. leonina in dogs and cats at 2.9% and 3.4%, respectively. Prevalence was highest in the Eastern Mediterranean region (7.2% for dogs and 10.0% for cats) and was significantly higher in stray dogs (7.0% vs. 1.5%) and stray cats (7.5% vs. 1.8%) than in pets. The findings indicate that, worldwide, ~26 million dogs and ~23 million cats are infected with Ta. leonina; these animals would shed substantial numbers of Ta. leonina eggs into the environment each year and might represent reservoirs of infection to other accidental or paratenic hosts. It is important that populations of dogs and cats as well as other canids and felids be monitored and dewormed for Ta. leonina and (other) zoonotic helminths.

1. Introduction

Archeological findings dating back 320 centuries provide evidence that humans and animals (including dogs and cats) co-habited and benefited from their association through mutual protection, hunting, shepherding and transport [1,2]. There are numerous breeds of dogs and cats, which have a wide diversity of roles and are most commonly kept as companions [3,4]. The human-animal bond provides benefits with regard to mental health and physical well-being [1]. Working dogs are engaged as assistants to entertain, shepherd livestock, conduct search and rescue and detect illicit food, drugs and human trafficking [4,5,6,7]. Dogs and cats play an important role in comparative medical studies of diabetes, narcolepsy and cancers [4,8,9,10]. Dogs are increasingly being used for the early detection of cancers [11], and it has been hypothesized that some canine infections may reduce the severity of human infection, such as the current pandemic with COVID-19 [12].
Global dog and cat populations are ubiquitous and are estimated at 900 million (500 million of which are stray or feral) and 700 million (480 million of which are stray), respectively (https://www.worldatlas.com, https://www.carodog.eu and https://www.carocat.eu). These figures are likely underestimated because dogs and cats are not registered in many countries and roam freely. In 2019, it was estimated that about one quarter of all European households owned at least one pet; in 2018, the total numbers of companion dogs and cats were estimated at 85.2 and 103 million, respectively (https://www.statista.com). In the USA, ~63.4 and 42.7 million families owned a dog or a cat (https://www.iii.org). Total numbers of dogs owned in the USA are estimated at 89.7 million and cats at 94.2 million (https://www.iii.org). In Australia, 40% of families have dogs, 27% have cats and 61% have either or both; in 2019, totals of 5.1 million pet dogs and 3.8 million pet cats were estimated (https://animalmedicinesaustralia.org.au). The close association of domestic and stray dogs and cats with humans necessitates attention to their health and welfare, as they can pose a public health threat through more than 60 zoonotic infections as well as scratches, bites, allergies, accidents and noise pollution [6,13,14,15].
Parasitic roundworms (nematodes) of the family Ascarididae (“ascarids”) cause amongst the most widespread and important zoonotic infections [16,17,18]. Ascarids of canids and felids are relatively large nematodes which, as dioecious adult worms, usually inhabit the lumen of the small intestines (rarely stomach or large intestine), where they live on gut contents. Adult worms of Toxocara canis and Toxocara cati are commonly found in dogs and cats; Toxocara malaysiensis is found in cats in parts of Asia [19,20,21,22], and Toxascaris leonina infects both dogs and cats [23]. Both T. canis and T. cati can cause serious disease in puppies and kittens, whereas Ta. leonina is considered less pathogenic.
The life cycles of Ta. leonina, T. canis and T. cati are well known, but that of T. malaysiensis has yet to be described [3,24,25,26,27,28,29,30,31]. While Ta. leonina is directly transmitted via the oral route, T. canis and T. cati both have oral and/or transmammary transmission, and T. canis is also transmitted transplacentally. These routes are, to some extent, governed by the age, sex and immune status of the animals. Disease (toxocariasis) in dogs caused by T. canis manifests as unthriftiness and pot-bellied appearance, with intermittent diarrhoea and, in some cases, palpably thickened small intestine. Vomiting, sneezing and coughing can occur in experimental infection. T. cati infection in kittens is similar to that described for less severe T. canis infection in puppies. Ta. leonina is less pathogenic in young animals, undertaking (as a larval stage) only limited migration into the intestinal wall, and has a longer prepatent period (48–72 days) than T. canis (20–35 days) and T. cati (25–42 days)—these characteristics of Ta. leonina allow puppies and kittens to grow and develop prior to the health impacts of the adult worms [23].
T. canis and T. cati can infect paratenic or accidental host animals, including rodents, lagomorphs, birds [23,25,31,32,33,34,35] and also humans [36]. Ta. leonina is only transmitted orally, and the larvae have been recorded to infect paratenic hosts, such as mice, rabbits and chickens and occasionally humans as accidental hosts [23,25,31,32,33,34,35]. This species has been occasionally implicated in human infection and disease [37,38,39], but its zoonotic potential has been questioned [14,40].
Although rarely reported, it is possible that transmission to humans may be more common than presently recognized, particularly in geographical regions in which Ta. leonina infection in canids and felids is endemic and prevalent [38,40]. Epidemiological studies of Ta. leonina are scattered and have often been small/limited. Investigations have been conducted in selected geographical regions, but there has been no comprehensive review of the literature or attempt to estimate the prevalence of Ta. leonina infection in dogs or cats worldwide. Recently, several reviews were published on T. canis and T. cati [16,17,18]. The present study is the first comprehensive review and meta-analysis to estimate the pooled global prevalence of Ta. leonina infection and associated risk factors in dogs and cats.

2. Results

2.1. Eligible Studies, Their Characteristics and Data Sets

Figure 1 summarises the numbers of publications at each stage of the process. Our search resulted in the identification of 1520 articles, 1362 of which were excluded, following the removal of duplicates and the screening of titles and abstracts. In total, 158 articles with full-texts were assessed for eligibility; 91 and 55 studies of dogs and cats, containing 117 and 65 data sets, respectively, were included in this meta-analysis. These studies provided data for 119,317 dogs and 25,364 cats from 40 and 28 different countries, respectively, from all continents. In total, 74,794/15,114 animals (i.e. dogs/cats) were examined in Europe, 30,880/4222 in North America, 5736/2784 in the Western Pacific region, 3409/1877 in the Eastern Mediterranean region, 2577/319 in Africa, 345/1048 in South America and 1576/0 in South-East Asia. In total, 96,187 and 19,200 pet dogs and cats, 10,031 and 4169 stray dogs and cats and 5966 and 1995 indeterminate (no specified type) of dogs and cats were studied, respectively. Moreover, 7133 working dogs were also tested for Ta. leonina infection. The salient descriptive characteristics of these studies are given in Tables S1 and S2.

2.2. Global and Regional Prevalence Rates of Toxascaris leonina Infection in Dogs

For the 117 data sets, 3229 of 119,317 dogs were diagnosed as having Ta. leonina infection, resulting in an overall, pooled global prevalence of 2.9% (95% CI, 2.2–3.8) (Table 1; Figure 2), with evidence of heterogeneity among studies (I2 = 98.0%, P < 0.001). In WHO-regions, the pooled prevalences (in descending order, with the range) were 7.2% (3.5–12.0%) in the Eastern Mediterranean region, 5.7% (1.4–12.2%) in South-East Asia, 3.6% (1.2–6.9%) in Africa, 2.6% (1.6–3.8%) in Europe, 2.0% (1.1–3.2%) in North America), 1.0% (0.1–3.4%) in the Western Pacific and 0.6% (0.1–2.1%) in South America. For countries with three or more eligible data sets, Iran (10.8%), India and Spain (5.3%), Slovakia (5.0%) and Canada (3.6%) exhibited some of the highest prevalences. Additional details pertaining to the prevalence of Ta. leonina infection in dogs in WHO-regions and individual countries are given in Table 1 and Figure 2.

2.3. Global and Regional Prevalence Rates of Toxascaris leonina Infection in Cats

For the 65 data sets, 511 of 25,364 cats were diagnosed as having Ta. leonina infection, resulting in an overall pooled global prevalence of Ta. leonina infection in cats of 3.4% (95% CI, 2.3–4.8%; Table 2), with evidence of heterogeneity among studies (I2 = 95.5%, P < 0.001). In WHO-regions, pooled prevalences were 10.0% (3.3–19.4%) in the Eastern Mediterranean region, 4.3% (0.3–11.9%) in South America, 1.9% (0.9–3.3%) in Europe, 1.4% (0.4–2.8%) in the Western Pacific and 0.01% (0.0–0.1%) in North America. For Africa, we identified only three eligible data sets from two publications for Nigeria, from which a prevalence of 38.7% for Ta. leonina infection was calculated. There were no data for the South East Asian region. For countries with three or more eligible data sets, the highest prevalences were inferred for Nigeria (38.7%), Iran (13.7%), Russia (4.0%) and Brazil (3.3%). Other details pertaining to the prevalence of Ta. leonina infection in cats in WHO-regions and individual countries are given in Table 2 and Figure 3.

2.4. Prevalence According to Type of Animals and Selected Study Characteristics

Subgroup analyses conducted according to the “type of animal” studied (Table 3) revealed that the prevalence of Ta. leonina infection in stray dogs (7.0%, 4.3–10.3%) was significantly higher (P < 0.001) than in working (3.9%, 1.9–7.2%), “indeterminate-type” (3.0%, 0.8–6.5%) or pet (1.5%, 0.9–2.3%) dogs (P < 0.001). Moreover, the global prevalence of Ta. leonina infection was 7.5% (4.0–11.8%) in stray, 3.3% (2.2–4.6%) in indeterminate-type and 1.8% (0.9–2.9%) in pet cats, with a significant difference between these subgroups (P < 0.001). Subgroup analyses, conducted according to sample size, revealed the lowest (1.0%) and highest (4.0%) prevalences in studies with sample sizes of ≤500 and ≥5000 animals. Studies conducted after 2005 indicated non-significantly lower prevalences (P = 0.09). With regard to study quality, those with a moderate risk of bias (7.5%) had significant higher prevalences than studies with a low risk of bias (2.5%) (P < 0.001). More detail is given in Table 3.

2.5. Impact of Socio-demographic, Geographical and Climatic Parameters on Prevalence

We also performed subgroup analyses with respect to socio-demographic, geographical and climate parameters, to attempt to establish the source of heterogeneity and also the effects of these parameters on the prevalence of Ta. leonina infection in dogs and cats (Table 4). When the pooled prevalence was stratified according to the income-level of people in a country, the highest prevalences were estimated for countries with low to middle income-levels (7.5%, 3.8–12.2%) and the lowest for those with high income-levels (1.4%, 1.0–1.8%). According to geographical latitude, the highest prevalence was seen at latitudes of 0–10° (9.7%, 2.7–19.9%) and the lowest at latitudes of 40–50° (1.8%, 1.2–2.4%). With respect to longitude, the highest and lowest prevalences were estimated at longitudes of 40–50° (6.9%, 5.6–19.0%) and ≥ 120° (0.4%, 0.1–0.8%), respectively. The highest prevalences were estimated at a mean relative environmental humidity of 41–59% (6.9%, 4.3–9.9%), a mean environmental temperature of 19–25 °C (6.9%, 3.5–11.1%) and a precipitation range of 251–500 mm (5.4%, 3.5–7.7%). More detail is given in Table 4.
With respect geographical parameters, meta-regression analysis showed a non-significant decreasing trend in prevalence with increasing geographical latitude (coefficient [C] = −0.0006, P = 0.14) and longitude (C = 0.00009, P value = 0.37). Considering climatic parameters, a marginally-significant decreasing trend was observed for increasing mean relative humidity (C = 0.001, P = 0.05). Moreover, a non-significant increasing trend in prevalence was seen with increasing mean environmental temperature (C = 0.0008; P = 0.32). Finally, a non-statistically significant decreasing trend was seen for increasing annual precipitation (C = −00002, P = 0.09) (Figure S1; panels A–F).

3. Discussion

Here, we undertook a systematic review and meta-analysis of published studies to estimate the prevalence and distribution of the Ta. leonina infection in dogs and cats worldwide. The global prevalence of Ta. leonina infection in dogs was 2.9% (2.2–3.7%) and 3.3% (2.2–4.6%) in cats. Worldwide, we estimated that ~26 million dogs and ~23 million cats are infected with Ta. leonina. There were significant differences in prevalence, depending on geographical region, owners’ income-levels in particular countries, type of animal (e.g., stray or pet) and study characteristics (cf. Table 1; Table 2).
The high prevalences of Ta. leonina infection estimated for the Eastern Mediterranean and African regions and low prevalences for the European, North American and the Western Pacific regions are in accordance with recent estimates for T. canis and T. cati infections in dogs and cats. [16,17]. These findings need to be interpreted with some caution due to the differences in the “types” and numbers of animals included in the different publications and the limited number of studies for some geographical regions (e.g., Eastern Mediterranean, Africa, South-East Asia and South America) (Tables S1 and S2). Subgroup analyses showed that stray animals and studies with low sample sizes had significant higher prevalences of Ta. leonina infection compared with pet animals and studies with large sample sizes, consistent with previous studies of Toxocara [16,17]. Subgroup analysis indicated that prevalence of Ta. leonina infection is significantly lower in countries with a high level of income per capita (e.g., European, Western Pacific and North American regions) compared with those with low or middle income-levels (e.g., Mediterranean, Africa and South America), again in accord with recent studies of Toxocara [16,17]. The latter difference might be explained by the adverse impact of socioeconomic (income- and education-levels) and political factors (including political instability or war) in some countries on veterinary care and programs to control stray animal populations.
The higher prevalences of Ta. leonina infection in stray dogs (6.6% vs. 1.5%) and cats (8.0% vs. 1.6%) compared with pets suggests a greater role of strays in contaminating the environment and facilitating transmission. The higher prevalences in stray animals was anticipated based on previous studies of Toxocara species [16,17] but needed to be independently evaluated, even though Ta. leonina belongs to the same nematode family (Ascarididae). Such animals usually/often have a poor nutritional status, are susceptible to infections, are not under veterinary care and are not treated with anti-parasitic drugs [16,41,42] and, thus, are likely “persistent” reservoirs of Ta. leonina.
Subgroup and meta-regression analyses revealed that the prevalence of Ta. leonina infection had a non-significant decreasing trend in recent years, like Toxocara infections in dogs and cats [16,17]. Increased knowledge of pet owners about the importance of the health of their animals and increased anti-parasite treatments may explain, to some extent, this trend [43,44]. With regard to geographical and climatic parameters, the non-significant higher prevalence of Ta. leonina infection in both dogs and cats in areas with low geographical latitudes and longitudes means higher temperature, lower relative humidity and annual precipitation likely relate to beneficial survival and embryonation rates of Ta. leonina eggs in the environment, as suggested for Toxocara infections in these animals [16,17,36,45,46].
Although this systematic review is the first to explore the prevalence of Ta. leonina infection in dogs and cats worldwide, it has some limitations in that: (i) some “grey” literature [47]—produced by organisations external to traditional academic or commercial publishers—may have gone undetected; (ii) data were not available for numerous countries, and thus, our estimates may sometimes not be representative in all countries and regions; (iii) the main aim of most publications included was to study T. canis and/or T. cati or other small intestinal parasites, and the finding of Ta. leonina was a “side issue”, so precise information on sex, age and/or location of animals was often not reported; and (iv) there was significant heterogeneity among studies, which is a commonly observed feature of global prevalence studies [48,49]. The comprehensiveness of the literature search, the data from >40 countries, the large numbers of dogs and cats included and the subgroup and meta-regression analyses indicate that the prevalence estimates are relatively reliable.

4. Methodology

This systematic review and meta-analysis was conducted using a standard protocol, according to the Preferred Reporting Items for Systematic Reviews and Meta-Analyses (PRISMA) [50].

4.1. Search Strategy and Selection Criteria

Two independent investigators (A.M. and M.F.) systematically screened five international databases (i.e., Web of Science, Scopus, PubMed, EMBASE and SciELO) for peer-reviewed papers, published from 1 January 1990 to 1 July 2019, to retrieve all publicly accessible data on the prevalence of Ta. leonina infection in dogs and cats. No geographic or language limitations were applied to the search procedure. A combination of the following search terms was used: “Toxascaris leonina”, “Ta. leonina”, “Toxascaris”, “intestinal parasites”, “gastrointestinal helminth”, “endoparasites”, “epidemiology”, “prevalence”, “incidence”, “dog”, “canine”, “puppy”, “cat”, “feline”, and “kitten”, alone or combined with the Boolean operators ‘OR’ and/or ‘AND’. The online tool "Google Translate" (https://translate.google.com/) was employed to access publications in languages other than English. For the systematic review, dogs and cats were included if Ta. leonina eggs were detected in fecal or hair samples, or Ta. leonina adult worms were found upon postmortem examination. All published works retrieved were imported into the program Endnote v.X7 and duplicate records removed. Two investigators (A.R. and V.F.O.) independently screened titles and abstracts and eliminated all studies that were unequivocally assessed as irrelevant in relation to the aim of the review. The abstracts of all remaining studies were saved in separate word files for the subsequent assessment of inclusion criteria. All potentially eligible articles were downloaded from online resources; if required, additional information was obtained from corresponding authors of a particular article.
Full texts of articles were assessed independently by two investigators (Y.F. and V.F.O.) for their suitability; any disagreement about inclusion/exclusion was resolved through discussion with the principal investigator (A.R.) to achieve a consensus. Publications were included in the current systematic review if they satisfied all of the following inclusion criteria: (1) peer-reviewed original research articles or short communications, which reported the prevalence of Ta. leonina in dogs or cats; (2) sample size of > 30 for dogs or cats; (3) fecal or hair examination method to detect and identify Ta. leonina eggs or a postmortem examination technique to identify adult Ta. leonina; (4) published between 1 January 1990 and 1 July 2019; (5) full-texts were available; and (6) precise information was reported on sample size(s) and the specific identity of the eggs or worms found. Publications were excluded if they did not meet all of these criteria or if they were review articles, systematic reviews, editorials or case reports.

4.2. Data Extraction and Quality Assessment

After assessing all eligibility criteria for each publication, relevant data and information were extracted independently by two authors (M.F. and A.M.) and collated in a Microsoft Excel spreadsheet (2016 version; Microsoft, Redmond, WA, USA) in a blinded manner. The extracted data and information were meticulously reappraised for accuracy by a third investigator (A.R.). Any disagreement or inconsistency was discussed and resolved to reach a consensus decision about inclusion or exclusion. Information from each eligible article (including the first author’s last name, publication year, study period, WHO-defined region, country, city, type of dogs and cats (pet or stray), sample size and number of Ta. leonina-positive samples) was extracted and entered into a spreadsheet in the program Microsoft Excel. The different types of dogs and cats studied in individual eligible published articles and reports were categorized into distinct groups (see Tables S1 and S2).
For each eligible publication, we estimated the pooled prevalences of Ta. leonina infection according to WHO-defined regions (Africa, Eastern Mediterranean, Europe, South-East Asia, the Americas and the Western Pacific) [51], World Bank’s income-level (https://datahelpdesk.worldbank.org), mean annual temperature, mean relative humidity, mean annual rainfall and geographical latitude and longitude; we considered North America and South America separately, because there are significant differences in terms of socio-demographic and climate conditions in these areas (https://en.wikipedia.org/wiki/Americas). Different data sources were employed to specify the geographical and climatic status of cities and regions (https://www.timeanddate.com/, https://en.climate-data.org/ and https://gps-coordinates.org/) [16].
To assess the quality and the risk of bias for each eligible publication, we used the Joanna Briggs Institute (JBI) Prevalence Critical Appraisal Tool [52]. Accordingly, a checklist was designed to appraise the quality of records for inclusion into this systematic review and meta-analysis (Table S3). Here, two trained authors (V.F.O. and M.F.) independently appraised the quality of each record; if a discrepancy arose, the final decision for inclusion or exclusion was made by the leader investigator (A.R.). Publications given scores of 7–10, 4–6 or 1–3 were ranked as having “low”, “moderate” and “high” risks of bias, respectively.

4.3. Meta-Analysis

In this systematic review, all analyses were conducted using the random effects model to estimate the pooled global prevalence of Ta. leonina infection in dogs and cats, as described previously [16,17,53,54]. Global and regional prevalences in WHO-regions or countries were recorded using a 95% confidence interval (CI). Heterogeneity among studies was computed using the Cochran Q and I2 statistics to define the degree of heterogeneity employing a cut-off value of 50% [55]. To assess the source of heterogeneity between studies, subgroup and meta-regression analyses were conducted. Subgroup analyses were carried out according to WHO-regions, types of cats and dogs, income-levels of countries, study characteristics (sample size, publication year and risk of bias), geographical latitude and longitude and climatic parameters (mean relative humidity, annual temperature and annual precipitation). In the meta-analysis, publication bias was not computed, because it is considered irrelevant for prevalence studies [56]. All statistical analyses were performed using STATA v.13 (STATA Corp., College Station, TX, USA), and a P-value of < 0.05 was considered as significant.

5. Conclusions

This study estimated overall prevalences of Ta. leonina infection of 2.9% (~26 million) in dogs and 3.3% (~23 million) in cats worldwide, and it intends to inform veterinary and medical practitioners about the need for intervention programs to reduce the burden of Ta. leonina and other ascaridoid infections in dogs and cats, particularly strays, focused on minimizing their transmission to paratenic or accidental host animals.

Supplementary Materials

The following are available online at https://0-www-mdpi-com.brum.beds.ac.uk/2076-0817/9/6/503/s1. Figure S1: Results of meta-regression analyses of the prevalence of Toxascaris leonina infection in dogs and cats according to: (panel A) demonstrating a statistically non-significant decreasing trend in prevalence over time in more recent years; (panels B and C) geographical latitude and longitude, showing statistically non-significant downward trend in prevalence with increasing geographical latitude and longitude; (panel D) relative humidity, showing statistically significant downward trend in prevalence with increasing relative humidity; and (panels E and F) mean environmental temperature and annual precipitation, showing non-statistically significant upward and downward trends in prevalence in areas with a higher mean temperature and relative humidity, respectively. “ES” refers to effect size (= prevalence rates). Table S1: Main characteristics of all eligible studies reporting prevalence of Toxascaris leonina infection in dogs. Table S2: Main characteristics of all eligible studies reporting prevalence of Toxascaris leonina infection in cats. Table S3: Questions from the Joanna Briggs Institute Prevalence Critical Appraisal Tool.

Author Contributions

Conceptualization, A.R. and R.B.G.; methodology, A.R., V.F.O., A.M. and M.F.; software, S.M.R. and Y.F.; validation, A.R., T.W. and A.H.; formal analysis, A.R. and S.M.R.; investigation, Y.F.; resources, A.M.; data curation, V.F.O. and M.F.; writing—original draft preparation, A.R. and R.B.G.; writing—review and editing, A.R., R.B.G. and C.N.L.M.; visualization, A.R.; supervision, R.B.G.; project administration, A.R. and R.B.G.; funding acquisition, R.B.G. All authors have read and agreed to the published version of the manuscript.

Funding

Funding from the Australian Research Council (ARC), National Health and Medical Research Council (NHMRC) of Australia, Yourgene Health Singapore, Melbourne Water and the University of Melbourne is gratefully acknowledged. (R.B.G.).

Acknowledgments

This research was supported by the Health Research Institute at the Babol University of Medical Sciences (IR.MUBABOL.HRI.REC.1398.129), Babol, Iran (A.R.).

Conflicts of Interest

The authors declare no conflicts of interest. The funders had no role in the design of the study; in the collection, analyses or interpretation of data; in the writing of the manuscript or in the decision to publish the results.

References

  1. Gee, N.R.; Mueller, M.K. A systematic review of research on pet ownership and animal interactions among older adults. Anthrozoös 2019, 32, 183–207. [Google Scholar] [CrossRef] [Green Version]
  2. Wang, G.-d.; Zhai, W.; Yang, H.-c.; Fan, R.-x.; Cao, X.; Zhong, L.; Wang, L.; Liu, F.; Wu, H.; Cheng, L.-G.; et al. The genomics of selection in dogs and the parallel evolution between dogs and humans. Nat. Commun. 2013, 4, 1–9. [Google Scholar] [CrossRef] [Green Version]
  3. Sprent, J.; Barrett, M.G. Large roundworms of dogs and cats differentiation of Toxocara canis and Toxascaris leonina. Aust. Vet. J. 1964, 40, 166–171. [Google Scholar] [CrossRef]
  4. Serpell, J.; Barrett, P. The Domestic Dog: Its Evolution, Behavior and Interactions with People, 2nd ed.; Cambridge University Press: Cambridge, UK, 2016; pp. 247–270. [Google Scholar]
  5. Campbell, K.L.; Corbin, J.E.; Campbell, J.R. Companion animals: Their Biology, Care Health, and Management, 2nd ed.; Pearson Prentice Hall: Upper Saddle River, NJ, USA, 2005. [Google Scholar]
  6. Macpherson, C.N. Dog zoonoses and human health: A global perspective. CAB Mini Rev. 2013, 8, 1–2. [Google Scholar]
  7. Zeagler, C.; Byrne, C.; Valentin, G.; Freil, L.; Kidder, E.; Crouch, J.; Starner, T.; Jackson, M.M. Search and rescue: Dog and handler collaboration through wearable and mobile interfaces. In Proceedings of Proceedings of the Third International Conference on Animal-Computer Interaction, Association for Computing Machinery, New York, NY, USA, 15–17 November 2016. [Google Scholar]
  8. Paul, M.; King, L.; Carlin, E.P. Zoonoses of people and their pets: A US perspective on significant pet-associated parasitic diseases. Trends Parasitol. 2010, 26, 153–154. [Google Scholar] [CrossRef] [PubMed]
  9. Doke, S.K.; Dhawale, S.C. Alternatives to animal testing: A review. Saudi Pharm. J. 2015, 23, 223–229. [Google Scholar] [CrossRef] [Green Version]
  10. Hoffman, A.M.; Dow, S.W. Concise review: Stem cell trials using companion animal disease models. Stem Cells 2016, 34, 1709–1729. [Google Scholar] [CrossRef]
  11. Pirrone, F.; Albertini, M. Olfactory detection of cancer by trained sniffer dogs: A systematic review of the literature. J. Vet. Behav. 2017, 19, 105–117. [Google Scholar] [CrossRef]
  12. Jurgel, J.; Filipiak, K.J.; Szarpak, Ł.; Jaguszewski, M.; Smerka, J.; Dzieciątkowski, T. Do pets protect their owners in the COVID-19 era? Med. Hypotheses 2020, 142, 109831. [Google Scholar] [CrossRef]
  13. Guay, D.R. Pet-assisted therapy in the nursing home setting: Potential for zoonosis. Am. J. Infect. Control 2001, 29, 178–186. [Google Scholar] [CrossRef]
  14. Robertson, I.D.; Thompson, R.C. Enteric parasitic zoonoses of domesticated dogs and cats. Microbes Infect. 2002, 4, 867–873. [Google Scholar] [CrossRef]
  15. Otranto, D.; Dantas-Torres, F.; Mihalca, A.D.; Traub, R.J.; Lappin, M.; Baneth, G. Zoonotic parasites of sheltered and stray dogs in the era of the global economic and political crisis. Trends Parasitol. 2017, 33, 813–825. [Google Scholar] [CrossRef] [PubMed]
  16. Rostami, A.; Riahi, S.M.; Hofmann, A.; Ma, G.; Wang, T.; Behniafar, H.; Taghipour, A.; Fakhri, Y.; Spotin, A.; Chang, B.C.H.; et al. Global prevalence of Toxocara infection in dogs. Adv. Parasitol. 2020, 109, 561–583. [Google Scholar] [PubMed]
  17. Rostami, A.; Sepidarkish, M.; Ma, G.; Wang, T.; Ebrahimi, M.; Fakhri, Y.; Mirjalali, H.; Hofmann, A.; Macpherson, C.N.; Hotez, P.J.; et al. Global prevalence of Toxocara infection in cats. Adv. Parasitol. 2020, 109, 615–639. [Google Scholar] [PubMed]
  18. Ma, G.; Rostami, A.; Wang, T.; Hofmann, A.; Hotez, P.J.; Gasser, R.B. Global and regional seroprevalence estimates for human toxocariasis: A call for action. Adv. Parasitol. 2020, 109, 273–288. [Google Scholar]
  19. Zhu, X.Q.; Jacobs, D.E.; Chilton, N.B.; Sani, R.A.; Cheng, N.A.B.Y.; Gasser, R.B. Molecular characterization of a Toxocara variant from cats in Kuala Lumpur, Malaysia. Parasitology 1998, 117, 155–164. [Google Scholar] [CrossRef] [Green Version]
  20. Gibbons, L.M.; Jacobs, D.E.; Sani, R.A. Toxocara malaysiensis n. sp. (Nematoda: Ascaridoidea) from the domestic cat (Felis catus Linnaeus, 1758). J. Parasitol. 2001, 87, 660–665. [Google Scholar] [CrossRef]
  21. Li, M.-W.; Zhu, X.-Q.; Gasser, R.B.; Lin, R.-Q.; Sani, R.A.; Lun, Z.-R.; Jacobs, D.E. The occurrence of Toxocara malaysiensis in cats in China, confirmed by sequence-based analyses of ribosomal DNA. Parasitol. Res. 2006, 99, 554–557. [Google Scholar] [CrossRef]
  22. Le, T.H.; Anh, N.T.L.; Nguyen, K.T.; Nguyen, N.T.B.; Gasser, R.B. Toxocara malaysiensis infection in domestic cats in Vietnam—An emerging zoonotic issue? Infect. Genet. Evol. 2016, 37, 94–98. [Google Scholar] [CrossRef]
  23. Parsons, J.C. Ascarid infections of cats and dogs. Vet. Clin. North Am. Small Anim. Pract. 1987, 17, 1307–1339. [Google Scholar] [CrossRef]
  24. Wright, W. Observations on the life history of Toxascaris leonina (Nematoda: Ascaridae). Proc. Helminthol. Soc. Wash. 1935, 2, 56. [Google Scholar]
  25. Okoshi, S.; Usui, M. Experimental studies on Toxascaris leonina. I. Incidence of T. leonina among dogs and cats in Japan. Jpn. J. Vet. Sci. 1967, 29, 185–194. [Google Scholar] [CrossRef] [PubMed]
  26. Okoshi, S.; Usui, M. Experimental studies on Toxascaris leonina. II. Diagnosis and treatment of toxascariasis in dogs and cats. Jpn. J. Vet. Sci. 1967, 29, 245–250. [Google Scholar] [CrossRef] [PubMed]
  27. Okoshi, S.; Usui, M. Experimental studies on Toxascaris leonina. III. Morphology of worms and eggs obtained from various animals. Jpn. J. Vet. Sci. 1967, 29, 329–336. [Google Scholar] [CrossRef] [Green Version]
  28. Okoshi, S.; Usui, M. Experimental studies on Toxascaris leonina. IV. Development of eggs of three ascarids, T. leonina, Toxocara canis and Toxocara cati, in dogs and cats. Jpn. J. Vet. Sci. 1968, 30, 29–38. [Google Scholar] [CrossRef] [Green Version]
  29. Okoshi, S.; Usui, M. Experimental studies on Toxascaris leonina. V. Experimental infection of dogs and cats with eggs of canine, feline and Felidae strains. Jpn. J. Vet. Sci. 1968, 30, 81–91. [Google Scholar] [CrossRef]
  30. Okoshi, S.; Usui, M. Experimental studies on Toxascaris leonina. VI. Experimental infection of mice, chickens and earthworms with Toxascaris leonina, Toxocara canis and Toxocara cati. Jpn. J. Vet. Sci. 1968, 30, 151–166. [Google Scholar] [CrossRef] [Green Version]
  31. Sprent, J.F. The life history and development of Toxascaris leonina (von Linstow 1902) in the dog and cat. Parasitology 1959, 49, 330–371. [Google Scholar] [CrossRef]
  32. Schulz, R. Ascaris joffi n. sp. und A. tarbagan n. sp.—zwei neue Askariden der Nagetiere. Zool. Anz. 1931, 94, 238–245. [Google Scholar]
  33. Nichols, R.L. The etiology of visceral larva migrans: I. Diagnostic morphology of infective second-stage Toxocara larvae. J. Parasitol. 1956, 42, 349–362. [Google Scholar] [CrossRef]
  34. Dubey, J.P. Migration and development of Toxascaris leonina larvae in mice. Trop. Geogr. Med. 1969, 21, 214–218. [Google Scholar] [PubMed]
  35. Karbach, G.; Stoye, M. Zum Vorkommen pränataler und galaktogener Infektionen mit Toxascaris leonina Leiper 1907 (Ascaridae) bei der Maus. Zentralbl. Veterinarmed. Reihe B 1982, 29, 219–230. [Google Scholar] [CrossRef]
  36. Rostami, A.; Ma, G.; Wang, T.; Koehler, A.V.; Hofmann, A.; Chang, B.C.; Macpherson, C.N.; Gasser, R.B. Human toxocariasis–a look at a neglected disease through an epidemiological ‘prism’. Infect. Genet. Evol. 2019, 104002. [Google Scholar] [CrossRef]
  37. Beaver, P.C.; Bowman, D.D. Ascaridoid larva (Nematoda) from the eye of a child in Uganda. Am. J. Trop. Med. Hyg. 1984, 33, 1272–1274. [Google Scholar] [CrossRef] [PubMed]
  38. Rausch, R.L.; Fay, F.H. Toxascaris leonina in rodents, and relationship to eosinophilia in a human population. Comp. Parasitol. 2011, 78, 236–244. [Google Scholar] [CrossRef]
  39. Hoberg, E.P.; Galbreath, K.E.; Cook, J.A.; Kutz, S.J.; Polley, L. Northern host-parasite assemblages: History and biogeography on the borderlands of episodic climate and environmental transition. Adv. Parasitol. 2012, 79, 1–97. [Google Scholar] [PubMed]
  40. Okulewicz, A.; Perec-Matysiak, A.; Buńkowska, K.; Hildebrand, J. Toxocara canis, Toxocara cati and Toxascaris leonina in wild and domestic carnivores. Helminthologia 2012, 49, 3–10. [Google Scholar] [CrossRef] [Green Version]
  41. Becker, A.-C.; Rohen, M.; Epe, C.; Schnieder, T. Prevalence of endoparasites in stray and fostered dogs and cats in Northern Germany. Parasitol. Res. 2012, 111, 849–857. [Google Scholar] [CrossRef]
  42. Taetzsch, S.; Bertke, A.; Gruszynski, K. Zoonotic disease transmission associated with feral cats in a metropolitan area: A geospatial analysis. Zoonoses Public Health 2018, 65, 412–419. [Google Scholar] [CrossRef]
  43. Deplazes, P.; van Knapen, F.; Schweiger, A.; Overgaauw, P.A. Role of pet dogs and cats in the transmission of helminthic zoonoses in Europe, with a focus on echinococcosis and toxocarosis. Vet. Parasitol. 2011, 182, 41–53. [Google Scholar] [CrossRef]
  44. Traversa, D. Pet roundworms and hookworms: A continuing need for global worming. Parasites Vectors. 2012, 5, 91. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  45. Rostami, A.; Riahi, S.M.; Holland, C.V.; Taghipour, A.; Khalili-Fomeshi, M.; Fakhri, Y.; Omrani, V.F.; Hotez, P.J.; Gasser, R.B. Seroprevalence estimates for toxocariasis in people worldwide: A systematic review and meta-analysis. PLoS Negl. Trop. Dis. 2019, 13, e0007809. [Google Scholar] [CrossRef] [PubMed]
  46. Fakhri, Y.; Gasser, R.; Rostami, A.; Fan, C.; Ghasemi, S.; Javanian, M.; Bayani, M.; Armoon, B.; Moradi, B. Toxocara eggs in public places worldwide — A systematic review and meta-analysis. Environ. Pollut. 2018, 242, 1467–1475. [Google Scholar] [CrossRef] [PubMed]
  47. Paez, A. Gray literature: An important resource in systematic reviews. J. Evid. Based Med. 2017, 10, 233–240. [Google Scholar] [CrossRef] [PubMed]
  48. Veroniki, A.A.; Jackson, D.; Viechtbauer, W.; Bender, R.; Bowden, J.; Knapp, G.; Kuss, O.; Higgins, J.P.; Langan, D.; Salanti, G. Methods to estimate the between-study variance and its uncertainty in meta-analysis. Res. Synth. Methods 2016, 7, 55–79. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  49. Rostami, A.; Riahi, S.M.; Gamble, H.R.; Fakhri, Y.; Shiadeh, M.N.; Danesh, M.; Behniafar, H.; Paktinat, S.; Foroutan, M.; Mokdad, A.H. Global prevalence of latent toxoplasmosis in pregnant women: A systematic review and meta-analysis. Clin. Microbiol. Infect. 2020, 26, 673–683. [Google Scholar] [CrossRef]
  50. Moher, D.; Shamseer, L.; Clarke, M.; Ghersi, D.; Liberati, A.; Petticrew, M.; Shekelle, P.; Stewart, L.A.; Group, P.-P. Preferred reporting items for systematic review and meta-analysis protocols (PRISMA-P) 2015 statement. Syst. Rev. 2015, 4, 1. [Google Scholar] [CrossRef] [Green Version]
  51. World Health Organization (WHO). List of Member States by WHO region and mortality stratum. World Health Report 2003, 2003, 182. [Google Scholar]
  52. Munn, Z.; Moola, S.; Riitano, D.; Lisy, K. The development of a critical appraisal tool for use in systematic reviews addressing questions of prevalence. Int. J. Health Policy Manag. 2014, 3, 123–128. [Google Scholar] [CrossRef] [Green Version]
  53. DerSimonian, R.; Laird, N. Meta-analysis in clinical trials. Control Clin. Trials 1986, 7, 177–188. [Google Scholar] [CrossRef]
  54. Foroutan, M.; Fakhri, Y.; Riahi, S.M.; Ebrahimpour, S.; Namroodi, S.; Taghipour, A.; Spotin, A.; Gamble, H.R.; Rostami, A. The global seroprevalence of Toxoplasma gondii in pigs: A systematic review and meta-analysis. Vet. Parasitol. 2019, 269, 42–52. [Google Scholar] [CrossRef] [PubMed]
  55. Higgins, J.P.; Thompson, S.G.; Deeks, J.J.; Altman, D.G. Measuring inconsistency in meta-analyses. BMJ 2003, 327, 557–560. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  56. Hunter, J.P.; Saratzis, A.; Sutton, A.J.; Boucher, R.H.; Sayers, R.D.; Bown, M.J. In meta-analyses of proportion studies, funnel plots were found to be an inaccurate method of assessing publication bias. J. Clin. Epidemiol. 2014, 67, 897–903. [Google Scholar] [CrossRef] [PubMed]
Figure 1. Flow diagram showing the search and selection methodology used, which follows PRISMA guidelines. Some studies investigated both dogs and cats (*).
Figure 1. Flow diagram showing the search and selection methodology used, which follows PRISMA guidelines. Some studies investigated both dogs and cats (*).
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Figure 2. Prevalence of Toxascaris leonina infection in dogs in different countries using geographic information system (GIS).
Figure 2. Prevalence of Toxascaris leonina infection in dogs in different countries using geographic information system (GIS).
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Figure 3. Prevalence of Toxascaris leonina infection in cats in different countries using geographic information system (GIS).
Figure 3. Prevalence of Toxascaris leonina infection in cats in different countries using geographic information system (GIS).
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Table 1. Global, regional and national prevalences of Toxascaris leonina infection in dogs, estimated from results extracted from 117 datasets from 40 countries.
Table 1. Global, regional and national prevalences of Toxascaris leonina infection in dogs, estimated from results extracted from 117 datasets from 40 countries.
WHO Region/CountryNumber of Data SetsTotal Number of SamplesNumber of Test-Positive SamplesPooled Prevalence (%) Established Using Meta-Analysis (95 % CI)Heterogeneity I2 (%)
Global117119,31732292.9 (2.2–3.8)98.0
Eastern Mediterranean1934091887.2 (3.5–12.0)94.6
Iran 12263916710.8 (4.7–19.0)96.2
Egypt5337112.9 (0.1–10.9)87.4
Jordan134092.6 (1.2–5.0)na
Iraq19311.1 (0.0–5.8)na
South-East Asia61576695.7 (1.4–12.2)94.0
Sri Lanka290119.5 (4.0–16.7)98.5
India 41486585.3 (1.0–12.3)95.4
Africa102577733.6 (1.2–6.9)91.5
Nigeria41418171.3 (0.1–3.3)71.9
South Africa2303213.0 (1.3–5.4)90.6
Gabon119810.5 (0.0–2.8)na
Malawi 140512.5 (4.2–26.8)na
Ethiopia 132692.8 (1.3–5.2)na
Zambia 1292206.8 (4.2–10.4)na
Europe5574,79425322.6 (1.6–3.9)98.6
Italy74799330.7 (0.2–1.4)68.9
Spain635953745.3 (2.0–10.0)95.2
Poland548423113.0 (0.9–6.2)91.3
Germany 436,8892190.6 (0.4–0.9)77.6
Belgium 434832492.5 (0.0–9.2)98.1
Greece 41915703.2 (1.1–6.3)87.0
Slovakia 41305635.0 (2.9–7.6)71.3
Portugal 349430.3 (0.0–1.2)0.0
Czech Republic 34778461.0 (0.6–1.4)31.1
Romania21314141.0 (0.5–1.6)0.0
Hungary 249060.8 (0.1–1.9)95.7
Albania 271360.7 (0.2–1.6)97.7
Turkey 252414327.0 (23.2–30.9)99.0
Russia 1814097011.9 (11.2–12.6)na
Switzerland 150571.4 (0.6–2.8)na
Netherland 144530.7 (0.1–2.0)na
Denmark117810.6 (0.0–3.1)na
England 117100.1 (0.0–2.1)na
Serbia 1134139.7 (5.3–16.0)na
Bulgaria18011.3 (0.0–6.8)na
North America1130,8802042.0 (1.1–3.2)96.4
Canada 62647943.6 (1.1–7.3)93.9
USA427,8551010.6 (0.2–1.1)94.0
Mexico 137892.4 (1.1–4.5)na
Western Pacific1557361611.0 (0.1–3.4)97.3
Japan 83150110.2 (0.0–0.6)39.2
Australia 4189330.1 (0.0–0.3)12.5
China261614319.8 (16.8–23.1)96.9
Malaysia 17745.2 (1.4–12.8)0.0
South America134520.6 (0.1–2.1)0.0
Brazil 134520.6 (0.1–2.1)0.0
Abbreviations: NA, not applicable; CI, confidence interval. WHO-regions (bold-type) sorted according to prevalence rates. Countries sorted according to the number of studies included.
Table 2. Global, regional and national prevalences of Toxascaris leonina infection in cats, estimated from results extracted from 65 datasets from 28 countries.
Table 2. Global, regional and national prevalences of Toxascaris leonina infection in cats, estimated from results extracted from 65 datasets from 28 countries.
WHO Regions/CountryNumber of Data SetsTotal Number of SamplesNumber of Test-Positive SamplesPooled Prevalence (%) Established Using Meta-Analysis (95 % CI)Heterogeneity I2 (%)
Global6525,3645113.4 (2.3–4.8)95.5
Africa331910438.7 (20.9–58.1)89.9
Nigeria331910438.7 (20.9–58.1)89.9
Eastern Mediterranean10187715510.0 (3.3–19.4)96.8
Iran 43164413.7 (3.8–28.0)89.5
Iraq23808822.8 (18.7–27.2)96.5
Egypt2283207.0 (4.2–10.3)95.0
Qatar 165810.2 (0.0–0.8)na
United Arab Emirates124020.8 (0.1–3.0)na
South America51048584.3 (0.3–11.9)94.2
Brazil 4583173.3 (0.0–11.6)92.1
Argentina1465418.8 (6.4–11.8)na
Europe3015,1141551.9 (0.9–3.3)92.6
Greece 51779160.9 (0.0–3.3)88.3
Netherland 4101861.0 (0.0–4.4)85.6
Spain31008151.3 (0.5–2.5)47.6
Germany 39523430.7 (0.0–5.2)97.8
Russia 3334144.0 (2.0–6.5)0
Italy2237123.8 (1.6–6.7)97.1
Turkey 2172177.8 (4.1–12.4)73.8
England 2142101.5 (0.5–5.0)96.5
Poland29030.9 (0.0–4.7)95.2
Finland 141110.2 (0.0–1.3)na
Hungary 1235177.2 (4.3–11.3)na
Czech Republic 113510.7 (0.0–4.1)na
Belgium 13000.1 (0.0–11.6)na
Western Pacific82784331.4 (0.4–2.8)80.2
Australia 51707271.6 (0.5–3.2)75.5
Japan 194220.2 (0.0–0.8)na
Taiwan 19611.0 (0.0–5.7)na
China13937.7 (1.6–20.9)na
North America9422260.01 (0.0–0.1)28.4
Canada 597630.0 (0.0–0.4)8.0
USA2288820.0 (0.0–0.2)77.0
Mexico 235810.2 (0.0–1.1)77.0
South-East Asian000nana
Abbreviations: NA, not applicable; CI, confidence interval. WHO-regions (bold-type) sorted according to prevalence rates. Countries sorted according to the number of studies included.
Table 3. The global prevalence of Toxascaris leonina in dogs and cats estimated according to a priori defined subgroups.
Table 3. The global prevalence of Toxascaris leonina in dogs and cats estimated according to a priori defined subgroups.
Parameters/SubgroupsNumber of DatasetsTotal Number of SamplesNumber of Test-Positive SamplesPooled Prevalence (%) Estimated using REM (95% CI)Heterogeneity I2 (%)
Type of dogs
Pet (domestic) dogs6496,18718521.5 (0.9–2.3)98.1
Working (domestic) dogs1671333243.9 (1.9–7.2)97.4
Stray (wild) dogs2810,0316747.0 (4.3–10.3)96.7
Indeterminate (not specified type) 959663793.0 (0.8–6.5)97.5
Type of cats
Pet (Domestic) cats3619,2002111.8 (0.9–2.9)93.9
Stray (wild) cats2541692927.5 (4.0–11.8)95.7
Indeterminate (not specified type) 4199583.3 (2.2–4.6)83.6
Sample size
≤50014026,00312464.0 (3.0–5.1)94.2
501–10002113,9091811.0 (0.6–1.6)87.7
1001–50001427,40810682.5 (0.9–4.9)99.1
≥5000777,36112451.0 (0.1–3.0)99.8
Implementation year
1990–19951916,9663741.9 (0.6–3.8)96.7
1996–2000652521296.2 (1.8–12.8)97.3
2001–20052823,77010054.7 (2.7–7.2)98.3
2006–20105768,8426892.3 (1.6–3.1)96.5
2011–20156425,29814503.2 (2.0–4.7)96.3
2016–201984553932.4 (0.6–5.2)95.4
Risk of bias
Low risk139141,45034812.4 (1.8–3.0)97.9
Moderate risk4332312597.5 (4.4–11.2)91.6
Abbreviations: REM, random effect meta-analysis; CI, confidence interval.
Table 4. The global prevalence of Toxascaris leonina infection in dogs and cats estimated according to different socio-demographic and geographic parameters.
Table 4. The global prevalence of Toxascaris leonina infection in dogs and cats estimated according to different socio-demographic and geographic parameters.
Parameter/SubgroupNumber of Data SetsTotal Number of SamplesNumber of Test-Positive SamplesPooled Prevalence (%) Established Using REM (95% CI)Heterogeneity I2 (%)
Income level
Low 30516153.2 (0.2–8.6)79.7
Lower middle2040752407.5 (3.8–12.2)95.4
Upper middle4817,96216847.4 (5.0–10.3)97.1
High 111122,12818011.4 (1.0–1.8)96.4
Latitude
0–10°1020621369.7 (2.7–19.9)97.1
10–20°92005582.1 (0.7–4.1)81.6
20–30°2560762613.6 (1.3–6.8)96.4
30–40°5219,7089164.9 (3.1–7.1)97.4
40–50°5081,4578711.8 (1.2–2.4)95.8
> 50°3633,37314982.0 (0.7–3.7)98.5
Longitude
0–10°4348,82010282.8 (1.6–4.2)97.7
10–20°2724,5162401.6 (1.0–2.4)97.6
20–30°2210,3744582.9 (1.4–4.8)95.2
30–40°1015001337.3 (2.5–14.1)93.7
40–50°15333029111.5 (5.6–19.0)96.9
50–60°1427091436.5 (2.3–12.4)96.0
60–70°000nana
70–80°931,9201481.0 (0.5–1.8)95.6
80–90°3399245.6 (0.1–17.0)86.1
90–100°000nana
100–110°1211,81610702.8 (0.5–6.6)98.0
110–120°716551643.8 (0.1–14.0)73.8
> 120°207642410.4 (0.1–0.8)67.5
Relative humidity (%)
< 407797966.4 (0.8–15.9)94.4
41–593071063156.9 (4.3–9.9)94.9
60–79127129,31031662.4 (1.8–3.2)98.0
≥ 801874681632.1 (0.7–3.9)92.7
Mean temperature (°C)
≤ 7.01812,53511393.5 (1.1–7.0)97.8
7.1–13.06894,93814472.6 (1.9–3.4)97.8
13.1–19.05829,8157812.2 (1.2–3.4)97.2
19.1–25.02638152776.9 (3.5–11.1)94.9
25.1–30.0123578962.7 (0.7–5.8)94.1
Precipitation (mm)
0–2501839921844.1 (1.6–7.6)94.9
251–5004014,2895655.4 (3.5–7.7)96.1
501–10008074,76225402.7 (1.8–3.7)97.9
1001–20004051,1304441.8 (1.1–2.6)96.6
> 2000450861.0 (0.1–3.4)68.2
Abbreviations: REM, random effect meta-analysis; CI, confidence interval.

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Rostami, A.; Riahi, S.M.; Fallah Omrani, V.; Wang, T.; Hofmann, A.; Mirzapour, A.; Foroutan, M.; Fakhri, Y.; Macpherson, C.N.L.; Gasser, R.B. Global Prevalence Estimates of Toxascaris leonina Infection in Dogs and Cats. Pathogens 2020, 9, 503. https://0-doi-org.brum.beds.ac.uk/10.3390/pathogens9060503

AMA Style

Rostami A, Riahi SM, Fallah Omrani V, Wang T, Hofmann A, Mirzapour A, Foroutan M, Fakhri Y, Macpherson CNL, Gasser RB. Global Prevalence Estimates of Toxascaris leonina Infection in Dogs and Cats. Pathogens. 2020; 9(6):503. https://0-doi-org.brum.beds.ac.uk/10.3390/pathogens9060503

Chicago/Turabian Style

Rostami, Ali, Seyed Mohammad Riahi, Vahid Fallah Omrani, Tao Wang, Andreas Hofmann, Aliyar Mirzapour, Masoud Foroutan, Yadolah Fakhri, Calum N. L. Macpherson, and Robin B. Gasser. 2020. "Global Prevalence Estimates of Toxascaris leonina Infection in Dogs and Cats" Pathogens 9, no. 6: 503. https://0-doi-org.brum.beds.ac.uk/10.3390/pathogens9060503

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