This systematic review was done using the Preferred Reporting Items for Systematic Reviews and Meta-Analysis (or ‘PRISMA’) guidelines.⁹ The protocol for the study was developed in conjunction with the NCDC panel of experts and a more detailed version of the protocol is available on request.

We searched Medline using PubMed for articles published in English between 01 January 2000 and 31 December 2017 with the search terms ‘antimicrobial resistance’, ‘antibiotic resistance’, ‘Vibrio cholerae’ and the names of the individual countries of sub-Saharan Africa. Additional searches were done in the African Journals Online database, using an additional search term of ‘antimicrobial susceptibility’. We also scanned a list of articles obtained from the NCDC to select eligible articles that conformed with our search terms.

Articles were included for this review provided they reported on the antimicrobial susceptibility profile of V. cholerae isolates from clinical specimens in sub-Saharan Africa and were published between January 2000 and December 2017. We included articles irrespective of whether the isolates were obtained as part of an outbreak investigation or from a hospital-based site using cross-sectional survey, provided they were from human specimens.

The titles and abstracts of all search results were listed and were thereafter reviewed to identify papers for full text review. The selection procedure is outlined in Figure 1. Forty-five papers were excluded, because all attempts to secure full text versions were unsuccessful. Names of authors from articles were not blinded before or after the full text review. We used predetermined inclusion and exclusion criteria to select papers for full review. Papers selected for full review after abstract review were retrieved as full manuscript papers through PubMed, HINARI, from the NCDC or by personal communication with the corresponding authors. Seventy-six review articles were excluded, and 45 papers did not report on the susceptibility pattern of V. cholerae and were also excluded. Twenty-eight papers were on environmental samples; hence, they were excluded. Nineteen articles were not from sub-Saharan Africa and 15 articles evaluated susceptibility to plant extracts and, consequently, they were all excluded. Eight articles were in French and six articles used isolates from animal sources and they were all excluded.

A database was created in which the study name, study period, susceptibility pattern, biochemical properties, genes and virulence factors of the V. cholerae isolates from countries of sub-Saharan Africa were recorded where applicable (Table 1). We could not adequately carry out a quantitative study, because most of the susceptibility patterns of the isolates were not recorded in actual numerical values. Most of the studies also did not report on the quality control procedure they used and some of the studies relied only on molecular detection of resistance genes.

An attempt to reduce bias within studies and between individual studies was done. The review was also conducted in a group with materials, articles and the papers double-checked by at least two members of the group.

The extracted data were reported as outlined by the authors using the susceptibility categorisation of the pathogens into sensitive, intermediate and resistant. We reported on the biochemical characteristics of the V. cholerae in terms of serogroup, biotype and serotype. We also reported on the clinical diagnosis for isolates in studies where diagnosis was stated. We also highlighted the use of molecular methods, genotyping or virulence features for the characterisation of isolates wherever such data were available.

Our search generated 267 articles after removal of duplicates. During abstract review, we excluded 242 articles, because they did not meet our inclusion criteria. Twenty-five articles were included in the final analysis.

One article reported resistance of V. cholerae from five sub-Saharan African countries and was therefore divided into five for convenience. In all, the articles obtained reported on 16 of the 47 countries within the sub-Saharan African region. One study (3.4% for each) was obtained from each of the following countries: Angola, Chad, Madagascar, Namibia, Senegal, South Africa and Togo. Two studies (6.9% for each) were from each of Cote d’Ivoire, Democratic Republic of the Congo, Ghana, Guinea Bissau, Mozambique, Tanzania and Zambia. Three (10.3%) studies were from Kenya and five (17.2%) were from Nigeria.

Twenty-four (82.8%) of the studies reported serogroup O1 as the only serogroup, while two (6.9%) studies reported the O1 serogroup coexisting with the non-O1/non-O139 serogroup, but even in those studies the O1 serogroup dominated. Three (10.3%) studies did not report on the serogroup status. None of the studies reported the O139 serogroup from any country in the region of sub-Saharan Africa.

Twenty two (75.9%) studies reported the El Tor biotype, while one (3.4%) study reported the existence of the El Tor and the atypical El Tor biotype. Six (20.7%) of the studies did not biotype their isolates. There was no report of the classical biotype from any of the studies.

Eight (27.6%) studies reported the Ogawa serotype as the predominant serotype, three (10.3%) studies reported on Inaba existing alone and six (20.7%) reported the Ogawa/Inaba coexisting together. The coexistence of Inaba/Ogawa/Hikojima was reported from one (3.4%) study. Eleven (37.9%) of the studies did not report on any of the serotypes.

Seventeen studies detected or confirmed cholera toxin and toxin-co-regulated pilus genes (ctxB, ctxA and tcpA).

Table 1 shows the characteristics of eligible articles that investigated resistance of V. cholerae from sub-Saharan Africa. Resistance was documented to trimethoprim-sulphamethoxazole (50% of the studies), ampicillin (43.3%), chloramphenicol (43.3%), streptomycin (30%), nalidixic acid (30%), nitrofurantoin (26.7%), ceftriaxone (20%), spectinomycin (10%), sulfonamide (6.7%), penicillin G (6.7%) and cloxacillin (3.3%). The antibiotics to which susceptible strains were reported were: tetracycline (46.7% of the studies), amoxicilin/clavulanic acid (6.7%), florfenicol (3.3%), azithromycin (3.3%), imipenem (3.3%), ciprofloxacin (3.3%), ofloxacin (3.3%) and erythromycin (3.3%).

Mutations in antibiotic resistance determinants (gyrA, parC, floR, strA, and strB) were detected in nine (31.1%) of the studies, while twenty (68.9%) studies did not conduct genotypic studies on the isolates.

The ICEVchAng2 and ICEVchInd5 were reported from seven (24.1%) of the studies while the other twenty-two (75.9%) studies did not perform this genotypic analysis.

The average prevalence of resistance to cell wall active agents by the V. cholerae organisms from 20 studies was 68.8% (100–0%). However, 25 studies reported on the resistance to fluoroquinolones with their total average of 44.0% (100–0%), while the average prevalence of resistance to inhibitors of nucleic acid, predominantly the sulphonamide and co-trimozaxole, was 92.0% from 25 studies (Table 1).

Twenty-seven studies reported 43.5% (100–0%) prevalence of resistance to protein synthesis inhibitors of 30S subunit, while the average prevalence of resistance to protein synthesis inhibitors of 50S subunit (Table 1) was 62.5% (100–0%) from 26 eligible studies.

In Angola, Ceccarelli et al. performed a retrospective study on V. cholerae O1 El Tor strains responsible for the 2006 outbreak. The isolates were resistant to all the major groups of antimicrobials tested and they demonstrated the appearance of a novel V. cholerae epidemic variant in Africa with a new CTXΦ arrangement previously described only in the Indian subcontinent.⁶ Kaas et al. investigated the 2010/2011 V. cholerae outbreak in Lake Chad basin around Cameroon. The outbreak strains were resistant to all the antimicrobials tested and, in addition, possessed the integrative conjugative element ICEVchInd5. This is said to be clonal and clustered, distant from the other African strains.¹⁰ Kacou-N’douba et al. documented resistance to chlorampenicol and cotrimoxazole during a cholera epidemic in 2011 from Cote d’Ivoire.¹¹

Smith and colleagues characterised V. cholerae O1 from Cote d’Ivoire, Democratic Republic of the Congo, Guinea Bissau, Mozambique and Namibia. All the isolates were of Ogawa serotype and positive for the ctxA gene. There was generalised resistance to nalidixic acid, chloramphenicol and cotrimoxazole in all isolates from the five countries.¹² In Democratic Republic of the Congo, Miwanda et al. documented resistance to cotrimoxazole, erythromycin and chloramphenicol. However, no resistance to fluoroquinolones was reported from this study.¹³ In two separate studies from Ghana, Eibach et al.¹⁴ and Opintan et al.¹⁵ documented resistance to trimethoprim-sulphamethoxazole, ampicillin and nalidixic acid. Dalsgaard and colleagues⁴ from Guinea Bissau demonstrated resistance to ampicillin, aminoglycosides, cotrimoxazole and tetracycline. Only colistin remained effective from their study. They also demonstrated that resistant isolates possessed a multi-resistance transmissible plasmid that encoded trimethoprim (dhfrXII) and aminoglycoside resistance (ant(3”)-1a).⁴

In Kenya, Urassa et al.¹⁶ documented resistance to ciprofloxacin, tetracycline, ampicillin, erythromycin and chloramphenicol by V. cholerae during two separate outbreaks.¹⁶ Another study from Kenya by Scrascia et al.¹⁷ showed resistance of V. cholerae to chloramphenicol, streptomycin and cotrimoxazole.¹⁷

Sang and colleagues¹⁸ in Kenya were able to demonstrate resistance to ciprofloxacin, tetracycline, ampicillin, erythromycin and chloramphenicol among V. cholerae isolates.¹⁸ Dromigny and colleagues¹⁹ conducted a study in Madagascar in 2002 among V. cholerae isolates and documented resistance to tetracycline, ampicillin, nalidixic acid and nitrofurantoin.¹⁹ Dengo-Baloi et al.²⁰ performed a study in Mozambique to determine the antibiotic resistance patterns of V. cholerae O1 Ogawa. The isolates were resistant to ampicillin, azithromycin, sulphamethoxazole, nalidixic acid and nitrofurantoin. Genes for cholera toxin (ctxA, rstR2, tcpA) and the virulence factors of ICEVchBan9 and ICEVchInd5 were elaborated.²⁰

Smith from Namibia²¹ characterised isolates of V. cholerae from a 2006/2007 outbreak and the isolates were all resistant to trimethoprim, sulphamethoxazole and streptomycin. The isolates possessing either the SfiI or NotI digestion sites were further analysed using advanced molecular techniques and it was demonstrated that they all have the same origin.²¹ Okeke and colleagues²² investigated an outbreak of acute gastroenteritis from Niger state, north-central Nigeria, where eight V. cholerae organisms were isolated. They all had the O1-serogroup and El Tor biotype. All of them were sensitive to tetracycline but resistant to trimethoprim, sulphonamide, spectinomycin and chloramphenicol.²²

Opajobi et al.²³ detected 34 strains of V. cholerae in Jos University Teaching Hospital over a one-year period. They were all of the O1 serogroup, El Tor biotype and Inaba serotype. They were all resistant to chloramphenicol, ampicillin, cloxacillin and penicillin G, but sensitive to tetracycline, ofloxacin and erythromycin.²³

A study done by Quilici et al.²⁴ using the V. cholerae isolates from the September/October 2009 outbreak of acute watery diarrhoea in north-eastern Nigeria and northern Cameroon implicated the serogroup O1 of the El Tor biotype and Ogawa serotype as the causative serotypes. The toxigenic genes of ctxA and ctxB were elaborated, in addition to detected mutations in the genes responsible for quinolone resistance. The ctxB gene was similar to the one detected in India. All of them were resistant to trimethoprim-sulphamethoxazole, ciprofloxacin, sulphonamide and nalidixic acid. All the isolates were resistant to tetracycline, but moderately susceptible to chloramphenicol and ampicillin.²⁴ In 2013, Marin and colleagues²⁵ described V. cholerae that were isolated from cases of acute watery diarrhoea outbreaks in Nigeria from 2009 to 2010. They reported that these toxigenic V. cholerae isolates were mostly of O1 serotype, and that atypical El Tor strains with the integrative conjugative element (ICE) of the sulfamethoxazole and trimethoprim (SXT) element, gyrA, cholera toxin (CTX) phage and cytidine triphosphate (CTP) synthetase clusters showed reduced susceptibility to ciprofloxacin and chloramphenicol.

Another study by Marin et al.²⁶ in 2014 characterised the whole genome of 13 strains of V. cholerae that were obtained from the 2010 outbreak. They all harboured an ICE (ICEVchNig1) that was characterised and shown to possess genes for trimethoprim, sulfamethoxazole, streptomycin and chloramphenicol resistance. They were found to have the same gene content and gene order with similar elements detected over 20 years ago in Haiti,²⁷ Angola⁶ and Bangladesh.²⁸ Dutilh and colleagues²⁹ used an innovative model to characterise the genomic variation of microbial genome with specific reference to V. cholerae isolates obtained worldwide with Nigeria inclusive. They were able to outline mobile functions of phages, prophages, transposable elements, and plasmids. They constructed a phylogenetic tree that revealed that the V. cholerae strain isolated in 2010 from Nigeria was closely related to strains already circulating in Nepal and Haiti.²⁹

In Senegal, the study by Sambe-Ba et al.³⁰ identified atypical El Tor V. cholerae O1 Ogawa that were resistant to streptomycin and cotrimoxazole. Ismail and colleagues³¹ from South Africa characterised a multi-resistant V. cholerae with resistance to ampicillin, cotrimoxazole, nalidixic acid, tetracycline, kanamycin and streptomycin. The isolates were positive for the SXT element, had quinolone resistance-determining mutations in the genes encoding GyrA (Ser83-Ile) and ParC (Ser85-Leu) and produced TEM-63-β-lactamase.³¹

A study in Tanzania by Moyo et al.³² documented resistance to ampicillin, amoxicillin-clavulanate, erythromycin, chloramphenicol, tetracycline, gentamicin and cephalothin. Another study in Tanzania by Mercy et al.³³ identified resistance of V. cholerae to furazoline, trimethoprim-sulphamethoxazole, polymyxin-B and streptomycin. The cholera virulence determinant genes ctxA, tcpA, ctxB and rtxC were also elaborated. In Zambia, Mwansa and colleagues³⁴ documented resistance of V. cholerae to trimethoprim, sulphamethoxazole, tetracycline and furazolidine. The cholera toxin and the virulence genes ctxA, rstR2, rfbO1 and tcpA were also elaborated.³⁴ Chiyangi et al.,³⁵ also from Zambia, detected resistance to cotrimoxazole, nalidixic acid and nitrofurantoin.³⁵

The most appropriate pictorial representation for meta-analytic data is the forest plot. However, we could not construct one because the studies we included did not provide the component data that is essential for a forest plot.

Antimicrobial resistance exists among V. cholerae isolates from sub-Saharan Africa and includes the most feared fluoroquinolone resistance variety as well as resistance to the cell wall active agents and antimetabolites. The volume of research from countries in sub-Saharan Africa on antimicrobial resistance trends in V. cholerae needs to be expanded and better explored. Guidelines on antimicrobial chemotherapy and standardisation of antimicrobial susceptibility testing need to be strictly adhered to.