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. 2017 Feb 23;15:14. doi: 10.1186/s12961-017-0178-8

Global toxocariasis research trends from 1932 to 2015: a bibliometric analysis

Sa’ed H Zyoud 1,2,
PMCID: PMC5324285  PMID: 28231792

Abstract

Background

Toxocariasis is a highly prevalent parasitic disease in the tropical regions of the world, with its impact on public health being typically underestimated. To better recognise the trends and characteristics of toxocariasis research, this study is a bibliometric analysis of the global toxocariasis research.

Methods

Searches were completed on April 5, 2016, using the Scopus database. A search without any language restriction was performed to extract publications dealing with toxocariasis. Terms related to toxocariasis were used to perform a title keyword search.

Results

A total of 2765 publications comprising 11 document types and published between 1932 and 2015 were included in the analysis. Articles were the most popular document form, accounting for 83.62% of all publications, followed by letters (3.80%) and reviews (3.4%). The annual number of research publications increased from 30 in 1980 to 111 in 2015, indicating that the number of publications on toxocariasis has increased slowly over the past 35 years. The United States of America and Japan are the predominant countries of origin, with 303 articles and 207 articles, respectively, followed by Brazil and the United Kingdom, with 180 (6.5%) each. The h-index for all the publications was 60. The highest h-index were for publications from the United Kingdom (h-index value = 43) and the United States (h-index value = 39); these two countries were also involved with the highest number of international collaborations, with 27 and 28 countries, respectively.

Conclusions

Developed countries, including the United States, Japan, the United Kingdom, France, Germany and Italy, are the world’s leaders in toxocariasis research, contributing to more than 34% of the total published literature. In addition, developing countries, such as Brazil, Poland, Argentina and India, showed a noticeable increase in published papers on toxocariasis research in recent years. A push for more collaboration is needed to achieve a superior research strategy related to toxocariasis at the global level from the viewpoint of epidemiological data, clinical aspects, medical ecology, molecular aspects and treatment practices associated with toxocariasis.

Keywords: Toxocariasis, Toxocara, Bibliometric, Scopus, Citations

Background

Toxocariasis is a highly prevalent parasitic disease in the tropical regions of the world, with its impact on public health being typically underestimated [13]. Human toxocariasis is acquired by ingestion of Toxocara canis or Toxocara cati embryonated eggs present in the soil or on hands and fomites contaminated by the faeces of infected dogs or cats; thus, it is considered to be a widespread zoonotic parasitic disease [1, 4]. Toxocara specimens were first illustrated by Werner in 1782; however, the genus was not recognized until 1905 by Stiles [5]. The clinical symptoms of toxocariasis in humans may vary from asymptomatic infection to localized symptoms (ocular and neurological) or severe systemic infection (visceral larva migrans), which is commonly complicated by blood eosinophilia [68].

Several studies have concluded that the cost of human toxocariasis is underestimated and understanding of its global impact remains poor because of the inadequacy of clinical awareness and an obvious lack of efficacy of laboratory, clinical and treatment interventions [1, 2, 4, 911]. To the author’s knowledge, to date, no bibliometric studies have assessed Toxocara and toxocariasis research over time at the global level. The bibliometric technique has already been applied to infectious diseases such as Mayaro [12], Zika [13], Chikungunya [14], leishmaniasis [15], malaria [16, 17], dengue [18, 19], Ebola [20], Middle East respiratory syndrome coronavirus [21] and Giardia lamblia [22].

Bibliometric analyses based on measuring the yearly publication output, publication types, source countries with their h-index, international collaboration research, source journals with their impact factors (IFs), and citation patterns are widely used by research funders or universities to assess research performance and to shed new light on future research trends. To better recognise the trends and characteristics of toxocariasis research, this study was designed to analyse the global toxocariasis research through bibliometric analysis.

Methods

The method of this study was derived from those of previous similar studies [17, 2325]. Searches were completed in April 5, 2016, using the Scopus database. A search without any language restriction was performed to extract publications dealing with toxocariasis. Scopus published by Elsevier is known to be the most common source of data for bibliometric studies in the sciences [17, 2527]. Compared with other databases, such as PubMed or Web of Knowledge, its records provide more comprehensive coverage [28] of the toxocariasis literature. The terms “toxocar*”, “nematode ophthalmitis”, “visceral larva migrans”, “ocular larva migrans”, “Nematode endophthalmitis”, “dog roundworm” and “cat roundworm” were used as keywords to search titles. These keywords were based on previous review articles [6, 2931]. The asterisk (*) was applied as a wildcard and enabled the search for variations of key terms. For example, entering “toxocar*” in the Scopus search engine would include the following terms: toxocariasis, toxocara – briefly, any probable word that might start with the seven letters (i.e. ‘toxocar’). Therefore, searching only titles would have resulted in data more related to the field of toxocariasis. No time period restriction was designated in the search concerning the start date, thus all publications prior to December 31, 2015, were included. In this study, a traditional bibliometric technique that included analysis of yearly publication output, languages, publication types, countries with their h-index, international collaboration research, source journals with their IFs, citation patterns and institutes was used. Documents published in 2016 or errata were excluded from the analysis. IFs were retrieved from the Journal Citation Reports (JCR 2014) [32]. The values of the h-index were extracted from the Scopus database for each country.

Ethical issues

The analysis in this study is based on a retrospective bibliometric technique; therefore, no ethical approval was required.

Statistical analysis

Microsoft Excel® and version 15 of SPSS® for Windows were used to perform statistical analysis. These software packages were used to generate data on frequency distribution, percentage, sum and average, and to create Fig. 1. Further analysis was introduced to obtain the top ten-ranked prolific countries, most prolific journals, most prolific institutions and most cited papers by using the 1-2-2-4 rule, which is known as the standard competition ranking.

Fig. 1.

Fig. 1

World Scopus publications with toxocariasis during 1932–2015

Results

A total of 2765 publications comprising 11 document types published between 1932 and 2015 were found. Articles were the most popular type of document, accounting for 83.62% of all the publications, followed by letters (3.80%) and reviews (3.4%). Of the 29 different languages identified, English (73.4%), Spanish (4.5%), French (4.5%), German (3.4%) and Polish (3.0%) were predominant. Figure 1 presents the distribution of publications on toxocariasis during the period of 1932–2015. The annual number of research publications increased from 30 in 1980 to 111 in 2015, showing that the number of publications on toxocariasis has increased slowly over the past 35 years.

Concerning the country of publication, 97 countries with publications on toxocariasis were identified. Table 1 shows the top 10 countries in descending order of publication number. The United States of America and Japan were the predominant countries, with 303 and 207 articles, respectively, followed by Brazil and the United Kingdom with 180 (6.5%) each. The h-index for all the publications was 60. The highest h-index were for publications from the United Kingdom (h-index value = 43) and the United States (h-index value = 39). The United States and the United Kingdom participated in the highest number of international collaborations, with 28 and 27 countries, respectively. In terms of the rate of publications from international collaborative research to total research for each country, the United Kingdom and Germany (28.9% and 25.3%, respectively) were the most active.

Table 1.

The 10 most productive countries in toxocariasis research

SCRa Country Number of documents (%) h-index Collaborations with foreign countries The number (%)b of publications with international collaborationc
1st United States 303 (11.0) 39 28 43 (14.2)
2nd Japan 207 (7.5) 27 19 33 (15.9)
3rd Brazil 180 (6.5) 23 10 16 (8.9)
3rd United Kingdom 180 (6.5) 34 27 52 (28.9)
5th France 115 (4.2) 22 10 14 (12.2)
6th Germany 79 (2.9) 16 14 20 (25.3)
7th Poland 78 (2.8) 14 5 11 (14.1)
8th Italy 61 (2.2) 14 8 10 (16.4)
9th Argentina 59 (2.1) 15 2 2 (3.4)
10th India 57 (2.1) 8 2 2 (3.5)

aEqual countries have the same ranking number, and then a gap is left in the ranking numbers

bPercentage of publications with international collaboration from the total number of publications for each country

c“International collaboration” defined as a document with at least two authors from different countries

SCR Standard competition ranking

Table 2 lists the 10 journals with the highest number of published documents referring to toxocariasis research from 1932 to 2015, with their IF. Veterinary Parasitology published the most documents (96, 3.47%), followed by Journal of Helminthology (82), Revista do Instituto De Medicina Tropical De Sao Paulo (58) and Parasitology Research (57), which had IFs of 2.460, 1.421, 1.007 and 2.098, respectively. The top 10 subject categories worldwide, with greater than 15 publications, are shown in Table 3. Medicine comprised 64.4% articles, followed by Immunology and Microbiology with 36.1%, and Veterinary with 13.1%.

Table 2.

Top 10 most productive journals, 1932–2015

SCRa Journal Number of documents (%) IF
1st Veterinary Parasitology 96 (3.47) 2.460
2nd Journal of Helminthology 82 (2.97) 1.421
3rd Revista do Instituto De Medicina Tropical De Sao Paulo 58 (2.10) 1.007
4th Parasitology Research 57 (2.06) 2.098
5th American Journal of Tropical Medicine and Hygiene 49 (1.77) 2.699
6th Journal of Parasitology 45 (1.63) 1.227
7th Transactions of the Royal Society of Tropical Medicine and Hygiene 37 (1.34) 1.839
7th Journal of the Egyptian Society of Parasitology 37 (1.34) NA
9th Parasite Immunology 36 (1.30) 2.143
10th Parasitology 35 (1.27) 2.560

aEqual journals have the same ranking number, and then a gap is left in the ranking numbers

SCR Standard competition ranking, NA Not available, IF Impact factor

Table 3.

The top 10 most subject categories in the field of toxocariasis during the study period

SCR Subject category Number of documents (%)a
1st Medicine 1780 (64.4)
2nd Immunology and Microbiology 998 (36.1)
3rd Veterinary 362 (13.1)
4th Agricultural and Biological Sciences 340 (12.3)
5th Biochemistry, Genetics and Molecular Biology 128 (4.6)
6th Neuroscience 79 (2.9)
7th Pharmacology, Toxicology and Pharmaceutics 57 (2.1)
8th Health Professions 28 (1.0)
9th Environmental Science 17 (0.6)
10th Chemistry 15 (0.5)

aTotal of publications exceeds 100% as one paper may fall under different subject categories

SCR Standard competition ranking

Table 4 presents the 20 most commonly cited toxocariasis publications between 1932 and 2015 [3352]. The IFs varied from 1.151 for the 4th most cited paper to 45.217 for the 9th most cited paper. The total number of citations per publication in this table ranged from 108 to 477. The most frequently cited article was published in Journal of Clinical Investigation by Del Prete et al. [37] from Italy, which had been cited 477 times.

Table 4.

The 20 most frequently cited publications related to toxocariasis from 1932 to 2015

SCR Authors (year of publication) Title Source title Cited by IF
1st Del Prete et al. [37] “Purified protein derivative of Mycobacterium tuberculosis and excretory-secretory antigen(s) of toxocara canis expand in vitro human T cells with stable and opposite (type 1 T helper or type 2 T helper) profile of cytokine production” Journal of Clinical Investigation 477 13.215
2nd Despommier [38] “Toxocariasis: Clinical aspects, epidemiology, medical ecology, and molecular aspects” Clinical Microbiology Reviews 364 17.406
3rd Glickman and Schantz [41] “Epidemiology and pathogenesis of zoonotic toxocariasis” Epidemiologic Reviews 303 6.667
4th Magnaval et al. [44] “Highlights of human toxocariasis” Korean Journal of Parasitology 248 1.151
5th Beaver et al. [34] “Chronic eosinophilia due to visceral larva migrans; report of three cases” Pediatrics 243 5.473
6th De Savigny [35] “In vitro maintenance of Toxocara canis larvae and a simple method for the production of Toxocara ES antigen for use in serodiagnostic tests for visceral larva migrans” Journal of Parasitology 225 1.227
7th Schantz [49] “Toxocara larva migrans now” American Journal of Tropical Medicine and Hygiene 188 2.699
8th De Savigny et al. [36] “Toxocariasis: Serological diagnosis by enzyme immunoassay” Journal of Clinical Pathology 164 2.915
9th Taylor et al. [51] “The expanded spectrum of toxocara disease” The Lancet 153 45.217
10th Magnaval et al. [43] “Application of the Western blotting procedure for the immunodiagnosis of human toxocariasis” Parasitology Research 144 2.098
11th Overgaauw [46] “Aspects of toxocara epidemiology: Human toxocarosis” Critical Reviews in Microbiology 134 6.020
12th Shields [50] “Ocular toxocariasis. A review” Survey of Ophthalmology 131 3.849
13th Wilder [52] “Nematode endophthalmitis” Transactions–American Academy of Ophthalmology and Otolaryngology 130 NA
14th Jacquier et al. [42] “Immunodiagnosis of toxocarosis in humans: Evaluation of a new enzyme-linked immunosorbent assay kit” Journal of Clinical Microbiology 119 3.993
15th Rubinsky-Elefant et al. [48] “Human toxocariasis: Diagnosis, worldwide seroprevalences and clinical expression of the systemic and ocular forms” Annals of Tropical Medicine and Parasitology 118 1.656
16th Barriga [33] “A critical look at the importance, prevalence and control of toxocariasis and the possibilities of immunological control” Veterinary Parasitology 117 2.460
17th Fisher [39] “Toxocara cati: An underestimated zoonotic agent” Trends in Parasitology 116 6.204
18th Glickman et al. [40] “Evaluation of serodiagnostic tests for visceral larva migrans” American Journal of Tropical Medicine and Hygiene 114 2.699
19th Overgaauw [47] “Aspects of Toxocara epidemiology: Toxocarosis in dogs and cats” Critical Reviews in Microbiology 110 6.020
20th Maizels et al. [45] “Characterization of surface and excretory-secretory antigens of Toxocara canis infective larvae” Parasite Immunology 108 2.143

SCR Standard competition ranking, NA Not available, IF Impact factor

Table 5 summarizes the top 10 productive institutes. Among them, two were from Brazil, and one each from Slovakia, Ireland, the Netherlands, Germany, Japan, the United States, the United Kingdom, Australia and Sri Lanka. The Instituto de Medicina Tropical de Sao Paulo was ranked 1st in institutional productivity with 44 scientific research publications, followed by the Parasitological Institute of the Slovak Academy of Sciences with 41 articles and the Universidade de Sao Paulo with 40.

Table 5.

The top 10 productive institutes in toxocariasis research

SCRa Institute Country Number of documents (%)
1st Instituto de Medicina Tropical de Sao Paulo Brazil 44 (1.59)
2nd Parasitological Institute of the Slovak Academy of Sciences Slovakia 41 (1.48)
3rd Universidade de Sao Paulo–USP Brazil 40 (1.45)
4th Trinity College Dublin Ireland 32 (1.16)
5th National Institute of Public Health and the Environment Netherlands 31 (1.12)
6th Tierarztliche Hochschule Hannover Germany 25 (0.90)
7th University of Miyazaki Japan 22 (0.80)
7th Cornell University United States 22 (0.80)
9th London School of Hygiene & Tropical Medicine United Kingdom 21 (0.76)
10th University of Queensland Australia 20 (0.72)
10th University of Peradeniya Sri Lanka 20 (0.72)

aEqual institutes have the same ranking number, and then a gap is left in the ranking numbers

SCR Standard competition ranking

Discussion

The current bibliometric study investigated the global toxocariasis research trends from 1932 to 2015. A bibliometric analysis of the patterns of publication outputs, publication types, journals with their IFs, source countries with their h-indexes, international collaboration research, institutional distributions and most-cited articles were conducted.

As shown in the current study, the annual number of research publications increased from 30 in 1980 to 111 in 2015, showing that the number of publications on toxocariasis has increased slowly in the past 35 years. An increase in research output has also been shown in similar research related to infectious diseases such as leishmaniasis [15], malaria [53] and Chagas disease [54]. In a comparison of the number of publications since 1980 concerning toxocariasis, leishmaniasis, malaria and Chagas disease, more rapid growth was observed in the number of papers focusing on leishmaniasis, of which 22,154 publications were published, followed by malaria (36,303 publications) and Chagas disease (5103 publications) compared with toxocariasis, on which 2281 publications were published. From this, it was concluded that, while there was a relative increase in research output in the field of toxocariasis since 1980, there was a higher interest in leishmaniasis, malaria and Chagas disease than in toxocariasis during this time period. This difference in interest between different issues can be attributed to discrepancies in the funding available for different diseases.

Developed countries, including the United States, Japan, the United Kingdom, France, Germany and Italy, are leading countries in toxocariasis research, contributing to more than 34% of the world’s total publications. Possible explanations for these findings may be rapid economic growth or the progress of scientific research systems in these countries. These findings were similar to those reported in earlier bibliometric studies [5557], which found that the economic growth of a country affected the quantity of research published by its researchers. Developing countries, such as Brazil, Poland, Argentina and India, showed a noticeable increase in published papers on toxocariasis research in recent years, which may have been coincident with a high prevalence of toxocariasis in these countries [31, 5860]. The United States and the United Kingdom had the highest number of collaborations. Multinational collaboration can help to draw attention to toxocariasis research. Another advantage of this collaboration would be that internationally collaborative publications are usually cited more often than those from individual countries [57, 61].

The most cited article, by Del Prete et al. [37] in 1991, was cited 477 times. This Italian study demonstrated that, in human, the T cell response to T. canis comes from the stimulation of T-helper type 2 cell type by the “excretory–secretory” antigens of T. canis [37]. The second most cited article was by Despommier [38] in 2003, and looked at epidemiology, clinical and molecular aspects of toxocariasis and the medical ecology associated with the disease.

To date, this is the first bibliometric study to assess the output of peer-reviewed publications on toxocariasis at the global level. Previous bibliometric studies have stated the limitations characteristic of using such an approach [23, 24, 26, 27, 6264]. First, the publications might not have been included in the analysis if toxocariasis or its related words were not mentioned in their titles, although these terms might have been found in the text. A second limitation was that this study did not include publications on toxocariasis that were in non-indexed journals and thus would not have been available in the Scopus database, such as those published in some Chinese journals.

Conclusions

This is the first study that investigated the global toxocariasis research trends from 1932 to 2015. The findings indicated that the number of articles published annually increased slowly. Developed countries, including the United States, Japan, the United Kingdom, France, Germany, and Italy, are leading countries in toxocariasis research, contributing to more than 34% of the world’s total publications. In addition, developing countries, such as Brazil, Poland, Argentina and India, demonstrated a noticeable increase in the number of publications related to toxocariasis in recent years. The United States is the world’s leading country in research on toxocariasis and international scientific collaborations on this disease. It is necessary to encourage and support research on toxocariasis in other areas of the world. A push for increased collaboration is needed to achieve a superior research strategy related to toxocariasis at the global level from the viewpoints of epidemiological data, clinical aspects, medical ecology, molecular aspects, and treatment practices associated with toxocariasis. Moreover, the search queries in the current area are biased toward publications in the English language. Therefore, it is important to know that most publications from China may be written in a language other than English, which limits access to these publications for non-Chinese speakers; this may have led to an underestimation of the research activities in non-English countries such as China.

Acknowledgements

None.

Funding

No funding was received for writing this study.

Availability of data and materials

Not applicable.

Authors’ contributions

SZ conceptualized the study, acquired and processed the data, performed statistical analysis, and wrote and approved the final manuscript.

Competing interests

The author declares that he has no competing interests.

Consent for publication

Not applicable.

Ethics approval and consent to participate

The analysis in this study is based on a retrospective bibliometric technique; therefore, no ethical approval was required.

Abbreviations

IF

impact factor

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