Human Toxoplasma gondii infection in Nigeria: a systematic review and meta-analysis of data published between 1960 and 2019

We conducted a systematic review and meta-analysis using the guidelines provided by Moher [36] for Preferred Reporting Items for Systematic Reviews and Meta-Analyses (PRISMA). Inclusion of data for quantitative synthesis was based on the PRISMA checklist (Additional file 1), and the infection of humans with Toxoplasma gondii was the outcome of interest. The review protocol was registered on PROSPERO International prospective register of systematic reviews with registration number CRD42019135416 and available from: http://​www.​crd.​york.​ac.​uk/​PROSPERO/​display_​record.​php?​ID=​CRD42019135416.

Six electronic databases: African Journals OnLine (AJOL), Google Scholar, PubMed, Scopus, Science Direct and Web of Science were systematically searched between 1st June and 30th April 2020 for literature published on T. gondii infection in humans in Nigeria between 1960 and 2019. Additional studies were obtained through searching of list of references of retrieved studies and by contacting editors of Nigerian biomedical journals. Full articles with only visible online abstracts were requested from authors and editors of the publishing journals through phone calls or e-mails. The MeSH search string employed in PubMed was “toxoplasmosis” OR “Toxoplasma” OR “Toxoplasma gondii” OR “Toxoplasma infections” AND “Prevalence” OR “Seroprevalence” OR “Seroepidemiology” AND “Humans” OR “Healthy individuals” OR “HIV patients” OR “Pregnant women” AND “North-central” OR “North-eastern” OR “North-western” Or “South-eastern” OR “South-south” OR “South-western” AND “Nigeria”. Search on AJOL was carried out on journal by journal bases within biomedical journals indexed in the database. Due to the large volume of data in Google Scholar, the study customised article search in this database based on year of publication for ease of sorting articles.

The quality of each article analysed was assessed independently using the 9 point Joanna Briggs Institute (JBI) critical appraisal instrument for studies reporting prevalence data [37]. The JBI checklist posed nine questions viz.: (1) Was the sample frame appropriate to address the target population? (2) Were study participants recruited in an appropriate way? (3) Was the sample size adequate? (4) Were the study subjects and setting described in detail? (5) Was data analysis conducted with sufficient coverage of the identified sample? (6) Were valid methods used for the identification of the condition? (7) Was the condition measured in a standard, reliable way for all participants? (8) Was there appropriate statistical analysis? (9) Was the response rate adequate, and if not, was the low response rate managed appropriately (Additional file 2)? Answers to the aforementioned questions for individual studies were respectively assigned scores of 0 or 1 for no or yes answers, while U or NA were used when a study does not clearly answer the question or when the question was not applicable to the study. For a study to be included in the quantitative synthesis, it was required to have a minimum quality assessment score of 6 (66.7%); that is answering yes to at least 6 of the 9 questions on the checklist.

To ensure data validation and increase the likelihood of detecting errors, literature search, screening of articles, selection of articles for eligibility and data extraction were performed by both authors (SNK and MNK) independently. However, in cases of discrepancies, both authors crosschecked data simultaneously and discussed issues until consensus was reached. Data pulled out from each published study were name of author, the year the study was carried out, the year it was published, sample size, number of positive cases, study location, study design, method of diagnosis, diagnostic target and characteristics of study population. Where specified, the gender and ages of study population were also extracted and individuals within the age brackets ≤17 years of age were categorised as children while those ≥18 years of age were categorised as adults. Where the study year for any article was not stated, the year preceding its publication year was considered as the year it was conducted.

In our PICOS, we answered questions such as: (1) What is the burden of Toxoplasma gondii infection in normal individuals, HIV patients and pregnant women from Nigeria? (2) Is the burden greater among immunocompromised than normal individuals? (3) What is the distribution pattern of the infection across Nigeria? For the purpose of the present study, an individual was said to be infected with T. gondii only if the individual tested positive for the parasite by microscopic, serological or molecular techniques, normal individuals refers to individuals without any history of pregnancy or any immunocompromised conditions like HIV/AIDS and neoplasia, pregnancy refers to a state where a woman carried an embryo or foetus for a period of ±9 months and HIV patients refer to people living with HIV/AIDS. More so, for the purpose of our analysis, diagnostic methods like polymerase chain reaction (PCR) and immunochromatography which were utilized by only one study, latex agglutination test (LAT) which was utilized by only two studies and studies with unidentified methods of diagnosis were grouped as others.

Pooled prevalence and their 95% Confidence Interval (CI) were estimated by the random-effects model [38]. Sub-group analyses were performed based on ages (Adult, children), gender (female, male), characteristics of study population (normal individuals, HIV patients and pregnant women) and geographic regions (North-central, north-east, north-west, south-east, south-south and south-west). Others were diagnostic methods (Dye test, ELISA, HAT, LAT, PCR, and RSAT), study period (1960–1975, 1976–1990, 1991–2005 and 2006–2019) as well as sample size (≤ 150, 151–300, 301–450 and > 450).

Heterogeneity among studies was evaluated using the Cochran’s Q-test while the percentage variation among studies due to heterogeneity was quantified using the formula I² = 100 × (Q-df)/Q; where Q is Cochran’s heterogeneity statistic and df is the degree of freedom which is determined by subtracting one from the number of studies analysed. I-square values of 0, 25, 50 and 75% were considered no, low, moderate and substantive heterogeneities respectively [39, 40].

Publication bias (across-study bias) was examined by funnel plots while the statistical significance was assessed by the Egger’s regression asymmetry test [41]. The unbiased estimates were calculated using the Duval and Tweedie non-parametric ‘fill and trim’ linear random method [42]. The robustness of a pooled estimate was tested by the single study omission analysis, and a study was considered to have no influence on the pooled prevalence if the pooled estimate without it (i.e number of studies = 49) was within the 95% confidence limits of the overall pooled prevalence when number of studies equals 50 [43]. Meta-regression analysis was performed for different sub-groups including year of conduct of study, diagnostic methods, geographic regions as well as age, gender and characteristics of the study population to determine the possible sources of heterogeneity.

The procedure for selection of eligible studies is presented in Fig. 1. A total of 79 studies resulted from the search of six electronic databases. Twenty five of the studies were duplicates and were removed after screening of titles. Fifty four of the studies were subjected to detailed review of abstract and full text. Four studies were thereafter removed for insufficiency of data on sample sizes and number of cases (n = 3) and lack of information on study location (n = 1). Fifty studies were subjected to the quantitative synthesis. None of the studies assessed for quality by the JBI critical appraisal instrument was excluded for lack of merit. Quality scores ranged between 6 and 8 (66.67–88.89%) of a total of 9 scores (Table 1 and Additional file 3).

Table 1 shows the characteristics of the eligible studies. Fifty studies examined 16,230 individuals for Toxoplasma gondii infection among Nigerians and reported prevalence rates ranging between 2.00 and 88.24%. Nine, 4, 10, 8 and 19 of the studies were reported in the north-central, north-eastern, north-western, south-south and the south-western regions respectively. Three studies utilized rapid slide agglutination test (RSAT) for diagnosis, 4 each were diagnosed using dye and haemagglutination tests, 28 of the studies utilized enzyme linked immunosorbent assay (ELISA) while 11 studies utilized other methods (immunochromatographic test 1, LAT 2, PCR 1 and unidentified tests 7). One study each targeted Toxoplasma-immunoglobulin M (IgM) and deoxyribonucleic acid (DNA), 20 studies targeted Toxoplasma-immunoglobulin G (IgG), 17 targeted both IgG and IgM, while 11 studies failed to state their diagnostic targets. Two studies were reported between 1960 and 1975, 6 between 1976 and 1990, 5 between 1991 and 2005 and 37 between 2006 and 2019. Twelve, 18, 13 and 7 of the studies had sample sizes of ≤150, 151–300, 301–450 and > 450 respectively.

The 50 studies were reported across 5 of the 6 regions of Nigeria as presented in Fig. 2. The nine (18.00%) studies reported across the north-central region were distributed as follow: one each in Kwara and Niger States, 2 each in Abuja and Benue State, and 3 in Plateau State. Four (8.00%) studies were reported in Borno State, North-east Nigeria while the 10 (20.00%) studies reported across the north-west region were from Kaduna and Sokoto (3 studies each) and 4 from Kano. One study each was reported from Akwa Ibom and Delta States and 3 each from Edo and Rivers States totally 8 (16.00%) studies from the south-south while the 19 (38.00%) studies distributed across the south-west; 1, 2, 6 and 10 were from Ogun, Osun, Oyo and Lagos States respectively. No study was reported in the south-east region.

Pooled prevalence and heterogeneities are presented in Tables 2 and 3 as well as Figs. 3 and 4. Fifty studies reported 5834 positive cases of Toxoplasma gondii infection among 16,230 individuals examined from 17 Nigerian States. Overall PP was 32.92% (95% CI: 27.89, 38.37; Q-p < 0.001) with ranges of 28.58 (95% CI: 16.28, 45.17; Q-p < 0.001) to 41.00% (95% CI: 25.61, 58.37; Q-p < 0.001) across geographic regions, 14.41% (95% CI: 5.32, 33.54; Q-p < 0.001) to 74.29% (95% CI: 57.49, 86.06; Q-p < 0.001) across methods of diagnosis, 28.75 (95% CI: 23.44, 34.71; Q-p < 0.001) to 86.82% (95% CI: 66.13, 95.69; Q-p: 0.760) across study periods and 30.22 (95% CI: 19.87–43.07; Q-p < 0.001) to 36.64% (95% CI: 24.15, 51.23; Q-p < 0.001) across sample size.

Pooled prevalence of T. gondii infection among adults and children were 36.93% (95% CI: 29.04, 45.59; Q-p < 0.001) and 18.52% (95% CI: 6.02, 44.63; Q-p < 0.001) respectively. Gender-based PP were 30.61% (95% CI: 22.95, 39.51; Q-p < 0.001) and 31.85% (95% CI: 21.79, 43.94; Q-p < 0.001) for females and males respectively. Pooled prevalence reported in both HIV-patients 31.68% (95% CI: 20.53, 45.41; Q-p < 0.001) and pregnant women 40.25% (95% CI: 33.19, 47.73; Q-p < 0.001) were significantly higher (p < 0.001) than that among normal individuals 23.32% (95% CI: 17.25, 30.75; Q-p: 0.001). Overall heterogeneity was 97.64% with a range of 85.76 to 99.17% (Tables 2 and 3).

The funnel plots (Fig. 5) and their respective bias coefficients for studies published in Nigeria as a whole (b: -3.48; 95% CI: − 7.53, 0.58; p: 0.091), northern (b: -3.10; 95% CI: − 7.90, 1.71; p: 0.194) and southern regions (b: -5.03; 95% CI: − 11.05, 0.99; p: 0.098) suggest insignificant publication bias. No outlying study capable of causing publication bias was identified and removed by the Duval and Tweedie’s trim and fill method (Additional file 4). As in Additional file 5, the sensitivity tests showed that all single-study omission estimates were within the 95% CI of the overall PP.

Meta-regression analysis (Tables 2 and 3) suggests that geographic regions (Q: 1.89; df: 4; p: 0.756), sample size (Q: 0.53; df: 3; p: 0.913), age (Q: 0.57; df: 1; p: 0.451) and gender of participants (Q: 0.04; df: 1; p: 0.835) were unlikely to be the sources of heterogeneity in the present analysis. However, the year of conduct of the studies (Q: 13.72; df: 3; p: 0.003), methods of diagnosis employed by the studies (Q: 20.65; df: 4; p < 0.001) and characteristics of study population (Q: 6.00; df: 2; p: 0.034) might be the possible causes of the heterogeneity in our analysis.