Background
Cysticercosis is an infection caused by the metacestode larval stage of the tapeworm
Taenia solium that affects pigs and humans, in areas where sanitation and veterinary control are poor. Pigs act as intermediate hosts by ingesting
T. solium eggs released in human feces. Humans are the only definitive hosts able to harbor adult tapeworms in the intestines, that may cause a rather mild illness called taeniasis. Humans, however, may also develop cysticercosis after ingestion of eggs, if the food/water or environment is contaminated with human fecal material, or by self-infection in case of adult worm carriage [
1]. Larval cysts (also called cysticerci) may settle in different tissues (muscles, skin) but are preferentially localized in the central nervous system (brain and spinal cord), causing neurocysticercosis, a disease associated with major morbidity, poor quality of life and significant cost for the health-care system, particularly in low-resource settings [
2,
3]. Depending on the number, size, stage, and location of the cysticerci as well as the host’s immune response, neurocysticercosis may cause a wide variety of neurological symptoms and signs, including seizures, headaches, focal deficits, psychiatric manifestations and cognitive impairment [
4‐
6]. On the other hand, some of the people carrying cysticerci in the central nervous system or in other locations may remain fully asymptomatic [
2]. An accurate diagnosis of neurocysticercosis almost always requires a combination of epidemiological, clinical, imaging and serological information, as very few elements are fully diagnostic in isolation. Definitions of probable or definitive diagnosis of neurocysticercosis are based on a set of neuroimaging and clinical/exposure major and minor criteria, which have been recently revised by Del Brutto et al. [
7]. Major neuroimaging criteria include cystic lesions, enhancing lesions, multilobulated cysts (all these lesions are usually referred to as active neurocysticercosis) and calcifications (referred to as inactive neurocysticercosis, in the absence of other active lesions). Well-standardized immunoassays are used as major “clinical/exposure criteria” and may detect either circulating
T. solium antigens, reflecting the presence of living cysticerci in any tissue (current/active cysticercosis), or antibodies, which may be present in case of exposure and in current or past infection [
8]. For this reason, sensitivity of antigen-based assays is usually lower than that of antibody-based assays for diagnosing cysticercosis [
9]. Of note, in low-resource settings, brain imaging and most immunoassays are usually not available or not affordable, making the definitive diagnosis of neurocysticercosis rarely possible [
3,
10] .
Neurological disorders account for approximately 10% of all admissions in African rural hospitals [
11‐
13]. However, the etiological spectrum has been hardly studied so far because of lack of diagnostic facilities [
14]. To fill this knowledge gap, we investigated the infectious etiologies of neurological disorders in the rural hospital of Mosango, province of Kwilu, Democratic Republic of Congo (DRC) [
15], as part of the NIDIAG project(“Better diagnosis of Neglected Infectious Diseases”,
https://nidiag.eu/) that investigated the etiologies of several challenging syndromes in various tropical countries. In this rural DRC setting where neuroimaging is not available, the contribution of neurocysticercosis in the neurological case load is unknown.
T. solium is highly endemic in the Bas Congo province, west of the capital Kinshasa, and is suspected to be present in other parts of the country as well [
15]. The aim of this study was to determine the frequency of positivity of antigen- and antibody-based
T. solium immunoassays in the clinical samples of the participants of the NIDIAG neurology study (neurology cohort), as well as to explore the association with the clinical presentation and final established diagnosis. A secondary objective was to determine the frequency of immunoassay positivity in another NIDIAG cohort of patients evaluated for persistent fever (> 7 days) in the same study hospital and during the same period (persistent fever cohort). This cohort of patients with non-neurological symptoms as used as comparator.
Results
Serum samples were available for 340 out of the 351 participants (97%) of the NIDIAG neurology cohort (Table
1). The mean age of this study population was 38.9 years [standard deviation: 17.7; range: 6–78); and the male-to-female ratio was 0.88 (159/181). Duration of neurological symptoms was more than 2 weeks in 190 (55.9%) of the evaluated patients and almost half had prior contact with a primary health care facility. Severe headache was the most frequent complaint, followed by gait/walking disorders and seizures. Confirmed targeted infections accounted for 84 (24.7%) of the final diagnoses while 156 (45.9%) cases were classified as non-communicable conditions, including mainly epilepsy and psychiatric disorders (Table
1). Death occurred in 26 patients (7.6%). The antigen-detecting assay was positive in 43/340 (12.6%; 95% CI 9.3–16.7%) participants of the NIDIAG neurology cohort. The antibody-detecting assay could be done in 314 samples, and was positive in four of them (1.3%; 95% CI 0.5–3.2%). All four antibody-positive cases were also
T. solium antigen positive.
Table 1
Baseline features, final diagnoses and outcome of 340 patients of the NIDIAG neurology cohort with available T. solium antigen results
Features at presentation | n (%) | n (%) | n (%) | |
Male sex | 159 (46.8) | 137 (46.1) | 22 (51.2) | 0.5 |
Female sex | 181 (53.2) | 160 (53.8) | 21 (48.8) | 0.5 |
Age > 20 years | 270 (79.4) | 231 (77.8) | 39 (90.7) | 0.05 |
Prior contact with primary care facility | 159 (46.8) | 141 (47.5) | 18 (41.9) | 0.4 |
Neurological symptoms > two weeks | 190 (55.9) | 168 (56.6) | 22 (51.2) | 0.5 |
Fever reported/documented | 99 (29.1) | 89 (30.0) | 10 (23.3) | 0.3 |
Severe headache | 156 (45.9) | 136 (45.8) | 20 (46.5) | 0.9 |
Severe headache without fever | 101 (29.7) | 86 (29.0) | 15 (34.9) | 0.4 |
Gait/walking disorders | 97 (28.5) | 86 (29.0) | 11 (25.6) | 0.6 |
Seizure | 84 (24.7) | 73 (24.6) | 11 (25.6) | 0.8 |
Focal sensory-motor deficit | 77 (22.6) | 67 (22.6) | 10 (23.3) | 0.9 |
Cognitive and/or behavior disturbance | 72 (21.2) | 60 (20.2) | 12 (27.9) | 0.2 |
Altered state of consciousness | 69 (20.3) | 61 (20.5) | 8 (18.6) | 0.7 |
Final diagnoses | n (%) | n (%) | n (%) | |
Confirmed targeted infections | 84 (24.7) | 76 (25.6) | 8 (18.6) | 0.3 |
Confirmed and suspected infections | 119 (35.0) | 107 (36.0) | 12 (27.9) | 0.2 |
Non-communicable conditions | 156 (45.9) | 134 (45.1) | 22 (51.2) | 0.4 |
Epilepsy | 60 (17.6) | 51 (17.2) | 9 (20.9) | 0.5 |
Psychiatric disorders | 53 (15.6) | 47 (15.8) | 6 (14.0) | 0.7 |
Myelo-radiculo-neuropathic syndromes | 37 (10.9) | 30 (10.1) | 7 (16.3) | 0.2 |
Cerebrovascular accident | 23 (6.8) | 20 (6.7) | 3 (7.0) | 0.9 |
Outcome | n (%) | n (%) | n (%) | |
Death | 26 (7.6) | 23 (7.7) | 3 (7.0) | 0.8 |
Within the neurology cohort, there were no differences regarding presenting features and final grouped or single diagnoses between
T. solium antigen-positive and -negative participants (Table
1). There was only a trend for higher frequency of patients older than 20 years in the
T. solium antigen-positive group (
P = 0.05).
In the neurology cohort, the frequency of T. solium antigen positivity was 12.6% in patients with reported/documented fever and 13.7% in patients without fever (P = 0.2). Slight non-significant variations in frequency were observed between the presenting neurological symptoms in the whole cohort or when restricted to non-febrile patients. T. solium antigen was positive in 8/84 (9.5%) of patients with confirmed targeted infection and in 22/156 (14%) of those finally diagnosed with non-communicable conditions, but this difference was not statistically significant (P = 0.3). Antigen positivity was observed in 9 of 60 (15%) patients diagnosed with epilepsy.
Of the 150 samples obtained from the patients with persistent fever, 148 could be analyzed with both antigen- and antibody-based tests. The male-to-female ratio was lower than in the neurology cohort (0.66; 59/89), but this difference was not statistically significant (Table
2). In contrast, mean age was 19.9 years (standard deviation: 16.2; range: 6–72) in this cohort, and was significantly lower than that of the neurology cohort (
p < 0.001).
T. solium antigen was positive in 7/148 (4.7%; 95% CI 1.9–9.5%). No single case of positive
T. solium antibody assay was found. As shown in Table
2, the frequency of
T. solium antigen positivity was significantly higher in the neurology compared to the persistent fever cohort (
P = 0.009; odds ratio 2.9; 95% confidence interval 1.3–6.6). When we stratified by age, the frequency of positivity remained higher in the neurology cohort, but was only statistically significant for subjects over 40 years of age.
Table 2
Epidemiological features and frequency of T. solium antigen and antibody positivity in the neurology and persistent fever cohorts evaluated at the rural hospital of Mosango, Democratic Republic of Congo
Epidemiological data |
Male sex, n (%) | 159 (47) | 59 (40) | 0.1 |
Female sex, n (%) | 181 (53) | 89 (60) | 0.1 |
Mean age (SD), years | 39.9 (17.7) | 19.9 (16.2) | < 0.001 |
Positive T. solium antigen assay |
Total group, n (%) | 43 (12.6) | 7 (4.7) | 0.009 |
Age group ≤20 years, n (%) | 4 (1.1) | 3 (2) | 0.4 |
Age group 21–40 years, n (%° | 17 (5) | 3 (2) | 0.1 |
Age group > 40 years, n (%) | 22 (6.4) | 1 (0.7) | 0.006 |
Positive T. solium antibody assay |
Total group n/n (%) | 4/314 (1.3) | 0/148 (0) | 0.3 |
Discussion
In this post-hoc analysis of a prospective cohort of patients presenting with neurological disorders in a rural hospital of Central Africa, we found that about 13% had evidence of circulating T. solium antigen in serum. There were no clear associations between presenting symptoms or final diagnoses and positivity for T. solium antigen. The frequency of antigen positivity was significantly higher in the neurology cohort than in the “comparator” persistent fever cohort (approximatively 5%), but a statistical difference was only observed in the subgroup of participants older than 40 years. Surprisingly, the antibody-based immunoassay was positive in only 1.3% of the neurological patients and in none of the persistent fever cohort.
This exploratory study has many limitations, most of which were largely acknowledged in previous publications reporting on the NIDIAG findings in DRC [
15,
20,
21]. The source NIDIAG study was not initially designed to investigate risk factors for neurocysticercosis since the presence of this disease had not been reported in humans in the region so far. The use of patients rather than a sample of the general population is another limitation of this post-hoc analysis as it does not enable the full magnitude of the underlying problem to be estimated. A complete diagnostic workup was restricted to a set of targeted infections for both the neurology and the persistent fever studies. In particular for the neurology study, the etiological workup was limited by the absence of advanced neurological investigations in this low-resource hospital. Consequently, no causative link can be formally established between the serological markers of
T. solium infection and the neurological presentation in the absence of brain/spinal imaging that could demonstrate cysticerci. Also, the persistent fever cohort was opportunistically used for comparison, but cannot be considered as a “control” group as such since the distribution of age groups was different. Finally, we acknowledge that the surprisingly low prevalence of
T. solium antibodies in the neurology cohort may be considered an important weakness. Indeed, one would have expected a proportion of antibody-positive participants, indicating exposure to
T. solium eggs, larger than that of antigen positivity. A possible explanation is that some degradation of the
T. solium immunoglobulins has inflated the false negative rate when the antibody assay was performed in 2018, while blood sampling took place between 2012 and 2015. However, transport and storage were rigorously monitored during the study and other serological investigations on the same stored samples did provide plausible results [
22]. Alternatively, this may have been related to differences in the circulating strains of
T solium, parasitic load or host characteristics compared to settings where the antibody-detection assay was validated [
23]. A failure of the LDBIO assay itself is unlikely since it performed well with positive and negative controls. However, sensitivity of this commercial assay has been reported in one study as substantially inferior to that of the reference Centers of Disease Control-developed enzyme-linked electroimmunotransfer blot (CDC-EITB), i.e. 13.3% versus 52.2% among 23 CT-confirmed neurocysticercosis cases tested [
24]. On the other hand, in a recent Mexican study on 58 NCC patients, the sensitivity of the LDBIO EITB was slightly higher (71.4%) than that of the CDC-EITB (66.1%) [
25]. These discrepancies between reference EITB test sensitivities need further investigation on a larger number of samples. In general, other types of commercial antibody-based-assays such as ELISA have limited sensitivities and specificities for diagnosing neurocysticercosis [
26].
The African continent reports the highest burden of human cysticercosis in the world, with pooled prevalence of circulating
T. solium antigens estimated at 7.30% (95% CI 4.23–12.31) and of antibodies at 17.37% (95%CI 3.33–56.20) in community-based epidemiological surveys [
25]. In DRC, the epidemiology of human and porcine cysticercosis is poorly understood. Some surveys in the animal markets of Kinshasa have revealed active cysticercosis in pigs originating from different DRC provinces [
18], including in more than 30% of those coming from Bandundu (the former name of the Kwilu province). Very high prevalence of human cysticercosis (proportion of
T. solium antigen positivity up to 21%) has been reported in the only community-based survey performed so far, in the province of Bas Congo [
16].
It is generally accepted that a higher proportion of neurocysticercosis cases is usually found in the older age categories [
27,
28]. We found some similar trend when looking at
T. solium antigen positivity, but cannot strongly support this observation since age categories were not evenly distributed in both cohorts and we did not specifically investigate neurocysticercosis. In contrast, we found no evidence of a difference in gender prevalence in our study. This agrees with findings reported in Bolivia [
29], but contrasts with data from Guatemala and Tanzania where a higher prevalence was found in females [
30,
31], and with findings in DRC and Vietnam, which showed a higher prevalence in males [
32,
33]. These differences might be explained by different living conditions and the distribution of household tasks between genders in those countries.
The prevalence of neurocysticercosis remains unknown in most low-resource settings, since neuroimaging is required to establish the diagnosis [
34]. The frequency of probable and definitive neurocysticercosis has been mainly investigated in patients with epilepsy, in whom the pooled estimate obtained from brain CT Scan-based studies was 30%, globally [
34] and in Latin America [
29]. Additional studies performed later on in Africa revealed that the proportion of neurocysticercosis in patients with epilepsy varied a lot according to the setting and could range from 15 to 50% [
24,
31,
32].
Diagnostic accuracy studies of antigen- and antibody-based assays for the specific diagnosis of neurocysticercosis (based on CT findings) in Africa have been limited to small case series. Using Del Brutto’s definition of probable or definitive neurocysticercosis in patients evaluated for epilepsy in Zambia, Gabriël et al. found a sensitivity of 44% (15 positive results/34 cases) for
T. solium antigen, when using a ratio of 1.0 as the cutoff, and a specificity of 90% (10). When restricting the analysis to patients with active neurocysticercosis (i.e. presence of viable cystic lesions,
n = 6), the sensitivity was 100% and the specificity 84%. Antibody-based Western Blot assays are usually reported as highly sensitive for neurocysticercosis in patients with more than one viable cystic lesion, but performance is much lower in cases of single lesions or of calcifications only. The specificity of antibody-based tests for neurocysticercosis is variable since distinction with previous exposure or cured infection cannot be made [
23]. As already mentioned, diagnostic performance of antibody-based ELISA assays is even poorer [
26].
Based on all these considerations, the sizeable proportion of participants with positive
T. solium antigen in both cohorts strongly suggests that active cysticercosis and neurocysticercosis are endemic in the study area, since false-positive results are infrequent for both conditions. Also, the high frequency of antigen positivity in patients with neurological disorders is compatible with the hypothesis that this infection plays some causal role [
4,
32]. It is worth reminding in addition that neurocysticercosis tends to become clinically apparent when the cystic lesions degenerate, through local inflammatory reactions, while active cysts alone usually cause little neurological symptoms [
35]. This may partly explain its age-dependent distribution.
Neuroimaging is absolutely necessary not only to accurately diagnose neurocysticercosis, but also to safely manage the potential risk of clinical deterioration due to anti-helminthic treatment (albendazole and/or praziquantel). While proven useful for epidemiological surveys and under study for assessing public health interventions (such as mass drug administration with anti-helminthic drugs in endemic regions), the utility of immunoassays is more questionable for clinical care, since no therapeutic decision can exclusively rely on their results [
23,
35]. Antigen- or antibody-based assays, whenever available at the point-of-care [
36,
37], could however be explored as an operational screening tool to select the subset of neurological patients who might benefit most from neuroimaging [
38]. Since such investigations would be difficult to obtain and expensive in rural Congo, choosing assays or cutoffs with high specificity to diagnose active neurocysticercosis (the main form responsive to anti-helminthic treatment) needs to be prioritized, in order to minimize the number of unnecessary referrals. Prior to such a study however, adequate treatment of neurocysticercosis has to be made available in African low-resource hospitals [
3].
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