Fever, bacterial zoonoses, and One Health in sub-Saharan Africa
Abstract
Although often underappreciated, a number of bacterial zoonoses are endemic in Africa. Of these, brucellosis, leptospirosis, Q fever, and rickettsioses are responsible for a substantial proportion of febrile illness among patients seeking hospital care. In this paper, we discuss the aetiology, epidemiology, clinical presentation, diagnosis, treatment and prevention of these bacterial zoonoses. To prevent and control bacterial zoonoses, strategies targeting both animals and humans are crucial. These may lead to better outcomes than strategies based exclusively on treatment of human infections. Such strategies are referred to as the ‘One Health’ approach; the collaborative effort of multiple disciplines to attain optimal health for people, animals and the environment.
The patient with fever in sub-Saharan Africa
Fever is a common symptom among patients seeking healthcare in sub-Saharan Africa where it may occur with or without localising features.1 With declines in malaria incidence worldwide and the wider availability of malaria diagnostic tests, the problem of malaria over-diagnosis has become apparent.2,3 Studies to describe major non-malaria causes of severe febrile illness in sub-Saharan Africa have identified the importance of bacterial bloodstream infections, HIV coinfections such as cryptococcal disease and disseminated tuberculosis, arbovirus infections and bacterial zoonoses such as brucellosis, leptospirosis, Q fever and rickettsioses.4,5 For example, research among 870 inpatients admitted with fever in northern Tanzania showed that malaria was the cause of fever in 14 (1.6%) participants, while bacterial, mycobacterial and fungal bloodstream infections accounted for 85 (9.8%), 14 (1.6%) and 25 (2.9%) infections, respectively. Arboviral infections were diagnosed in 55 (7.9%) patients enrolled in the study. Bacterial zoonoses were identified among 118 (26.2%) patients; 16 (13.6%) had brucellosis, 40 (33.9%) had leptospirosis, 24 (20.3%) had Q fever, 36 (30.5%) had spotted fever group rickettsioses and 2 (1.8%) had typhus group rickettsioses (Fig 1).6
Brucellosis
Aetiology
Brucellosis is caused by Brucella species, Gram-negative coccobacilli. Of a larger number of Brucella species with reservoirs in livestock and other animals, B abortus, B canis, B melitensis and B suis are recognized to cause human disease. The majority of human brucellosis worldwide is caused by B melitensis.7
Reservoir, source and mode of transmission
Goats and sheep are the major reservoirs of B melitensis. Cattle are the major reservoir of B abortus, while B canis is mainly found in canines, and B suis in domestic and feral swine. In areas where cattle coexist with goats or are fed sheep offal, cattle can be infected with B melitensis. Brucella localises to the reproductive tract and mammary glands of animals and may be present in the blood, reproductive tract secretions, milk and meat. Humans acquire the infection through direct contact, airborne transmission during aerosolisation and foodborne transmission. Risk factors for human brucellosis in sub-Saharan Africa include assisting goat or sheep births and having contact with cattle. Consuming boiled or pasteurised dairy products has been found to be protective against brucellosis.8
Incidence, complications and death
While it is well established that brucellosis is endemic in north Africa, the incidence of brucellosis is uncertain in many sub-Saharan African countries.4,9 A study from northern Tanzania demonstrated that brucellosis incidence was stable at 35 cases per 100,000 person-years during 2007–2008 and 33 cases per 100,000 person-years during 2012–2014.10 Prevelance estimates for chronic brucellosis are lacking. Data from retrospective studies indicate that the case fatality ratio for brucellosis is low, at approximately 1%.7 During pregnancy, brucellosis can cause spontaneous abortion and fetal infection.
Clinical presentation
The clinical presentation of brucellosis is protean. Acute infection often presents as a nonspecific febrile illness. Chronic forms of brucellosis include focal involvement of the osteoarticular, reproductive and central nervous system as well as hepatitis, liver abscesses, endocarditis, lobar pneumonia and pleural effusions.7
Diagnosis
Diagnostic confirmation of acute brucellosis relies upon isolation of Brucella species from culture of clinical specimens or a four-fold rise in Brucella antibody titre between acute and convalescent sera obtained at least 14 days apart.11 While blood culture sensitivity is 50–90%, the sensitivity of bone marrow is 15–20% higher. The sensitivity and specificity for acute disease of Brucella paired serum agglutination tests exceed 90% in endemic areas.12 Neither the US Centers for Disease Control and Prevention nor the World Health Organization (WHO) has a specific case definition for chronic brucellosis. Finally, nucleic acid amplification tests are promising, but diagnostic performance varies substantially with the type of samples tested and the extraction methods used.13 Using blood cultures and serology as reference standards, the sensitivity of Brucella spp nucleic acid amplification tests (NAATs) has been reported as 61.0% in whole blood samples, 94.0% in serum samples and 97.1% in tissue samples from patients with a clinically active disease.14,15
Treatment
Tetracyclines and a parenteral aminoglycoside, or tetracyclines and rifampin are recommended by WHO for treatment of human brucellosis. The treatment duration is 6 weeks, except for spondylitis and osteomyelitis where 8–12 weeks of therapy is needed.
Prevention and control
Brucellosis prevention and control is based on interventions among both animals and humans. Animal interventions include vaccination of animal populations; testing animals for infection and slaughtering those infected; and pasteurisation of dairy products. Interventions among humans include use of personal protective equipment, such as an overall apron, rubber gloves, boots, eye protection and mask for meat workers and for those dealing with aborting animals or animals undergoing parturition; and hygiene measures, minimally including rinsing of hands in approved disinfectants and washing with soap and water after contact with animals. Superficial injuries should be treated with an approved antiseptic, such as 1% chloramine solution. Intervention among humans are focused on specific groups such as abattoir workers and those dealing with aborting or parturient animals.
Leptosirosis
Aetiology
Leptospirosis is caused by spirochete bacteria in the genus Leptospira. There are 10 pathogenic species, and more than 250 pathogenic serovars. A large number of different Leptospira serogroups can cause human disease although predominant serogroups vary by year and by study.
Reservoir, source and mode of transmission
Pathogenic Leptospira have reservoirs in a wide range of animals including rodents and livestock and are shed in urine.16 The bacteria can survive for weeks to months in urine-contaminated water and soil. People are infected through direct or indirect contact with the urine of an infected animal. Rice farming, cleaning cattle waste, feeding cattle, farm work and increased exposure to cattle urine have been identified as risk factors for human leptospirosis in sub-Saharan Africa.17
Incidence, complications and death
A recent systematic review reported a prevalence of acute human leptospirosis in 2.3–19.8% of hospitalised patients with fever in Africa.18 Leptospirosis annual incidence in northern Tanzania has fluctuated from 75–102 per 100,000 people in 2007–2008 to 11–18 per 100,000 people in 2012–2014, suggesting dynamic transmission patterns.19 The case fatality ratio for leptospirosis is 5–15% among patients with severe illness. Among patients with pulmonary haemorrhage syndrome, the case fatality ratio can exceed 50%. Leptospirosis during pregnancy can cause fetal death.
Clinical presentation
Most infections are asymptomatic. Of symptomatic infections, 90% present as a nonspecific acute febrile illness 5–14 days after exposure, while 10% progress to severe illness with multi-organ dysfunction including renal failure, liver failure and pulmonary haemorrhagic syndrome.
Diagnosis
The diagnosis of leptospirosis is based on either a four-fold rise in Leptospira antibody titre between acute and convalescent sera obtained at least 14 days apart, or a single reciprocal titre of ≥1:800 measured by agglutination test.20 The isolation of Leptospira species from culture of clinical specimens is also a valid but insensitive diagnostic method. Due to the transience of leptospires in body fluids, whole blood should be cultured during the first week, and urine after the first week of illness. Finally, NAAT allows early detection of Leptospira with reasonable sensitivity and specificity.21
Treatment
Recommended treatments for leptospirosis are doxycycline or amoxicillin in case of mild disease, and penicillin G or ceftriaxone in severe disease. In patients with a high clinical suspicion, antimicrobial treatment should be initiated as soon as possible without waiting for laboratory confirmation. The duration of treatment in severe disease is usually 7 days.
Prevention and control
Leptospirosis prevention and control is based on interventions among both animals and humans. Intervention among animals include animal vaccination and rodent control. Preventing leptospirosis in humans is based on avoiding swimming or wading in water that might be contaminated with animal urine; use of personal protective equipment, such as an overall apron, rubber gloves, boots and eye protection for people at occupational risk, such as abattoir workers and dairy farmers; and personal hygiene. Personal hygiene measures include hand washing after using the toilet or handling animals, covering skin breaks with waterproof coverings, avoiding smoking, drinking or eating when handling livestock, and washing clothes after handling stocks.
Q fever
Aetiology
Q fever is caused by the obligate intracellular bacterium Coxiella burnetii, which can survive in harsh environments in a spore-like form.
Reservoir, source and mode of transmission
Goats, sheep and cattle are the main reservoirs of C burnetii. Infected animal birth products, urine, faeces and milk contain C burnetii, and spore-like forms contaminate dust. As a consequence, people can be infected by direct contact with milk, urine, faeces, and afterbirth of infected animals; breathing dust contaminated by infected animals; and consuming unpasteurised dairy products of infected animals. Transmission through blood transfusion, from a pregnant woman to her fetus, and sexual transmission have been reported.
Incidence, complications and death
C burnetii seroprevalence is 11–33% among small ruminants, ≤13% among cattle, and <8% among humans in African studies.22,23 In a human cohort study, Q fever accounted for 5% of febrile illness hospitalisations.24 Q fever is rarely fatal. An exception is Q fever related myocarditis that has a 25% case fatality ratio. The frequency of pregnancy complications in women developing Q fever is uncertain, although fetal death has been documented.
Clinical presentation
Of people infected with C burnetii, 50% will develop symptoms. Acute infection is characterised by fever usually accompanied by rigors and myalgia 2–3 weeks after exposure. Acute infection can be complicated by hepatitis, pneumonia and meningoencephalitis. Less than 5% of people infected with C burnetii develop a chronic infection that could persist for more than 6 months. The most common presentations of chronic Q fever are endocarditis, particularly in persons with underlying valvular disease, and vascular manifestations, including infection of vascular protheses and aortic aneurysm. Less frequent presentations of chronic Q fever include osteomyelitis and hepatitis.
Diagnosis
In the presence of clinical symptoms, the diagnosis of acute and chronic Q fever may include the detection of C burnetii by culture, polymerase chain reaction or immunohistochemistry. C burnetii culture requires biosafety level three laboratories and involves the inoculation of specimens onto conventional cell cultures, embryonated hen yolk sacs or laboratory animals. C burnetii NAAT can be applied to a wide range of clinical samples; its sensitivity is higher when applied to whole blood samples within 2 weeks of symptom onset. C burnetii immunohistochemistry in tissue can be performed using several techniques including immunoperoxidase staining, a capture enzyme-linked immunosorbent assay, an enzyme-linked immunosorbent fluorescence assay system, or monoclonal antibodies. Finally, serologic testing based on indirect immunofluorescent assay (IFA) can support the diagnosis of acute and chronic Q fever. The demonstration of a four-fold rise in phase II immunoglobulin G (IgG) by IFA between acute and convalescent serum samples taken 4 weeks apart is used to confirmed the diagnosis of acute Q fever. In contrast to acute infection, chronic Q fever is characterised by phase I IgG titres typically equal or greater than 1:1,024.25
Treatment
Patients with acute Q fever should receive doxycycline for 14 days. Patients with chronic Q fever should be treated with doxycycline and hydroxychloroquine for 18–24 months.
Prevention and control
Prevention and control of Q fever can include animal, environmental, and human interventions.26 Animal interventions include animal vaccination to reduce the shedding of the organisms and pasteurisation of dairy products. Environmental interventions are focused on reducing the risk of transmission of C burnetii to human communities and include placement of high vegetation barriers around animal holdings; indoor parturition, safe disposal of parturition materials and safe disposal of hides and offal; and reduction of the aerosolisation by increasing soil moisture through irrigation or concreting surfaces. Human interventions are focused on the minimisation of the human contact with infected materials. Contaminated materials should be handled in ways that minimise the risk of aerosolisation. Personal protective equipment, such as an overall apron, rubber gloves, boots, eye protection and respirator mask rated N95 or higher should be worn in case of potential exposure to infected materials.
Rickettsiosis
Aetiology
Rickettsial infections are caused by various bacterial species from the genus Rickettsia. Rickettsia spp are classically divided into spotted fever group (SFG) and typhus group. Several rickettsial pathogens have been reported in sub-Saharan Africa.
SFG rickettsioses
Among the SFG rickettsioses, R aeschlimanii, R africae (African tick-bite fever), R conorii (Mediterranean spotted fever), R sibirica (lymphangitis-associated rickettsiosis), and R felis are the most often reported from Africa.27
Reservoir, source and mode of transmission
SFG rickettsioses reservoirs include dogs and ruminants. While R aeschlimanii, R africae, R conorii and R sibirica are tick-borne infections, and R felis is flea-borne. Organisms can be transmitted by bites from these vector species or by inoculating infectious fluids or faeces from vectors into the skin. Inhaling or inoculating conjunctiva with infectious material may also cause infection for some of these organisms.
Incidence, complications and death
Spotted fever group rickettsioses accounted for 8.0% of the causes of fever in a population of 870 febrile inpatients in Tanzania.24 Case fatality ratio ranges from 1.0–4.0% for typhus group rickettsiosis.28,29
Clinical presentation
Symptoms develop 6–10 days after the bite and may include fever, headache, muscle pain, macular or maculopapular rash, local lymphadenopathy and an eschar at the bite site. Mediterranean spotted fever may present with a single eschar, whereas multiple eschars may be present in African tick-bite fever.
R typhi
R typhi (murine typhus or endemic typhus) is part of the typhus group rickettsioses and has been reported in sub-Saharan Africa.
Reservoir, source and mode of transmission
Rodents are the reservoir of R typhi. R typhi is transmitted to humans by fleas. Specifically, humans become infected when flea faeces containing R typhi contaminate disrupted skin or are inhaled into the respiratory tract.
Incidence, complications and death
Typhus group rickettsioses accounted for 0.5% of the causes of fever in a population of 870 febrile inpatients in Tanzania.24 Endemic typhus is often unrecognised and misdiagnosed and is rarely associated to adverse outcomes.
Clinical presentation
Endemic typhus is typically a mild disease characterised by fever, headache and a transient rash.
Diagnosis
The diagnosis of rickettsiosis is based on the detection of Rickettsia spp by cell culture of blood and tissue specimens, immunohistochemical methods applied to tissue specimens, or blood and tissue specimen NAAT. While NAAT sensitivity in blood is low, NAAT of biopsy of eschar or rash material is sensitive.30 Furthermore, a four-fold rise in Rickettsia spp antibody titre between acute and convalescent sera obtained at least 14 days apart measured by an IFA is diagnostic.31 However, because of cross-reactivity of immune responses to rickettsial antigens, antibodies are group-specific but not species-specific.
Treatment
Doxycycline is the treatment of choice for rickettsioses. Treatment of patients with possible rickettsioses should be started when disease is suspected and should not await confirmatory testing, as certain infections can be rapidly progressive. Treatment duration is 7 days.
Prevention and control
Rickettsioses prevention is based on both vector and human interventions. Vector interventions consist in the use of insecticides. Human interventions are based on limiting the exposure to the vectors. This goal could be achieved wearing protective clothing and using insect repellent, such as diethyl-m-toluamide and permethrin, when undertaking activities where human contact with ticks, mites or fleas may occur such as during bushwalking and camping in infected areas.
Bacterial zoonoses and One Health approaches
Although not widely appreciated or studied, bacterial zoonoses are likely to be endemic in many African countries and cause substantial human morbidity and mortality.6,32 In addition to causing human infections, bacterial zoonoses have important effects on the livelihoods of rural communities through their impacts on livestock fertility, growth, productivity and survival.7 Here, close contact with animals and their environments heightens risk for infection, human and livestock healthcare services are limited, and livestock represent a major source of nutrition and income for families.33 Despite their substantial impact on both human and animal health, bacterial zoonoses have been neglected because the burden of disease is poorly quantified is borne largely by disadvantaged populations with little political voice in low-resource areas. One Health is the collaborative effort of multiple disciplines to attain optimal and equitable health for people, animals and the environment.34 Bacterial zoonoses lend themselves to One Health approaches to management, prevention and control.
For clinicians working in low-resource settings, bacterial zoonoses present a number of challenges. From a diagnostic perspective difficulties include limited healthcare provider awareness;35 non-specific clinical presentation and frequent misdiagnosis with malaria;36 prior antimicrobial administration that may hamper the ability to detect bacteria;37 presentation later in the course of the illness when the bacteraemic phase has passed;37 lack of accurate tests at point-of-care and unavailability of confirmatory tests;38 and the limited diagnostic accuracy of single sample serology.39 Regarding patient management challenges, WHO Integrated Management of Adolescent and Adult Illness (IMAI) District Clinician Manual algorithms for severe febrile illness recommend ceftriaxone or ampicillin plus gentamicin.40 However, while these regimens would be effective for leptospirosis, they are not suitable for the treatment of brucellosis, Q fever and rickettsiosis.
Livestock and environmental interventions have the potential to effectively reduce the magnitude of bacterial zoonotic infections from the animal and environmental reservoirs, generating benefits to all who are epidemiologically linked with the source of the infection.30 The prevention and control of brucellosis, leptospirosis, Q fever and rickettsiosis is centred on approaches targeting animal reservoirs, environmental sources, vectors and humans. When implemented, such approaches contribute to better outcomes for human and animal health than those based exclusively on treatment of human infections.30 Both clinicians’ awareness and resources for the development and implementation of control measures will be crucial for addressing bacterial zoonoses in Africa.
Acknowledgements
We acknowledge Prof Matthew P Rubach, Robert Chuwa, Dr Kate M Thomas and the staff of Duke Collaboration at Kilimanjaro Christian Medical Centre (Moshi, United Republic of Tanzania).
- © 2019 Royal College of Physicians
References
- ↵
- ↵
- ↵
- Reyburn H
- ↵
- ↵
- Maze MJ
- ↵
- ↵
- Corbel MJ.
- ↵
- Cash-Goldwasser S
- ↵
- ↵
- Carugati M
- ↵
- Centers for Disease Control and Prevention
- ↵
- ↵
- ↵
- Morata P
- ↵
- Zerva L
- ↵
- Allan KJ
- ↵
- Maze MJ
- ↵
- Allan KJ
- ↵
- Maze MJ
- ↵
- Centers for Disease Control and Prevention
- ↵
- ↵
- ↵
- Wardrop NA
- ↵
- ↵
- ↵
- Clark NJ
- ↵
- ↵
- ↵
- ↵
- Parola P
- ↵
- Centers for Disease Control and Prevention
- ↵
- Grace D.
- ↵
- ↵
- Centers for Disease Control and Prevention
- ↵
- Zhang HL
- ↵
- ↵
- Levett PN
- ↵
- ↵
- ↵
- World Health Organization
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