About the Author(s)


Boyo C. Pare symbol
Alliance for International Medical Action (ALIMA), Dakar, Senegal

Alseny M. Camara symbol
Alliance for International Medical Action (ALIMA), Dakar, Senegal

Aminata Camara symbol
Ministry of Health, Agence Nationale de Sécurité Sanitaire, N’zérékoré, Guinea

Ministry of Health, Hôpital Régionale de N’zérékoré, N’zérékoré, Guinea

Moussa Kourouma symbol
Ministry of Health, Agence Nationale de Sécurité Sanitaire, N’zérékoré, Guinea

Ministry of Health, Hôpital Régionale de N’zérékoré, N’zérékoré, Guinea

Koivogui Enogo symbol
Ministry of Health, Agence Nationale de Sécurité Sanitaire, N’zérékoré, Guinea

Mohammed S. Camara symbol
Alliance for International Medical Action (ALIMA), Dakar, Senegal

Laurent Akilimali symbol
Alliance for International Medical Action (ALIMA), Dakar, Senegal

Sayadi Sani symbol
Alliance for International Medical Action (ALIMA), Dakar, Senegal

Eric Barte de Sainte Fare symbol
Alliance for International Medical Action (ALIMA), Dakar, Senegal

Papys Lame symbol
Alliance for International Medical Action (ALIMA), Dakar, Senegal

Nicolas Mouly symbol
Alliance for International Medical Action (ALIMA), Dakar, Senegal

Marta Lado Castro-Rial symbol
World Health Organization (WHO), Geneva, Switzerland

Billy Sivahera symbol
Alliance for International Medical Action (ALIMA), Dakar, Senegal

World Health Organization (WHO), Geneva, Switzerland

Mahamoud S. Cherif symbol
Centre National de Formation et de Recherche en Santé Rural de Maferinyah, Maferenya, Guinea

Abdoul H. Beavogui symbol
Centre National de Formation et de Recherche en Santé Rural de Maferinyah, Maferenya, Guinea

Dally Muamba symbol
Alliance for International Medical Action (ALIMA), Dakar, Senegal

Joachim B. Tamba symbol
Alliance for International Medical Action (ALIMA), Dakar, Senegal

Barry Moumié symbol
Ministry of Health, Agence Nationale de Sécurité Sanitaire, N’zérékoré, Guinea

Richard Kojan symbol
Alliance for International Medical Action (ALIMA), Dakar, Senegal

Hans-Joerg Lang Email symbol
Alliance for International Medical Action (ALIMA), Dakar, Senegal

Witten/Herdecke- University, Global Child Health, Witten, Germany

Citation


Pare BC, Camara AM, Camara A, et al. Ebola outbreak in Guinea, 2021: Clinical care of patients with Ebola virus disease. S Afr J Infect Dis. 2023;38(1), a454. https://doi.org/10.4102/sajid.v38i1.454

Note: Additional supporting information may be found in the online version of this article as Online Appendix 1

Original Research

Ebola outbreak in Guinea, 2021: Clinical care of patients with Ebola virus disease

Boyo C. Pare, Alseny M. Camara, Aminata Camara, Moussa Kourouma, Koivogui Enogo, Mohammed S. Camara, Laurent Akilimali, Sayadi Sani, Eric Barte de Sainte Fare, Papys Lame, Nicolas Mouly, Marta Lado Castro-Rial, Billy Sivahera, Mahamoud S. Cherif, Abdoul H. Beavogui, Dally Muamba, Joachim B. Tamba, Barry Moumié, Richard Kojan, Hans-Joerg Lang

Received: 08 June 2022; Accepted: 05 Dec. 2022; Published: 31 Jan. 2023

Copyright: © 2023. The Author(s). Licensee: AOSIS.
This is an Open Access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

Abstract

Background: Experience from the Zaire Ebolavirus epidemic in the eastern Democratic Republic of the Congo (2018–2020) demonstrates that early initiation of essential critical care and administration of Zaire Ebolavirus specific monoclonal antibodies may be associated with improved outcomes among patients with Ebola virus disease (EVD).

Objectives: This series describes 13 EVD patients and 276 patients with suspected EVD treated during a Zaire Ebolavirus outbreak in Guinea in 2021.

Method: Patients with confirmed or suspected EVD were treated in two Ebola treatment centres (ETC) in the region of N’zérékoré. Data were reviewed from all patients with suspected or confirmed EVD hospitalised in these two ETCs during the outbreak (14 February 2021 – 19 June 2021). Ebola-specific monoclonal antibodies, were available 2 weeks after onset of the outbreak.

Results: Nine of the 13 EVD patients (age range: 22–70 years) survived. The four EVD patients who died, including one pregnant woman, presented with multi-organ dysfunction and died within 48 h of admission. All eight patients who received Ebola-specific monoclonal antibodies survived. Four of the 13 EVD patients were health workers. Improvement of ETC design facilitated implementation of WHO-recommended ‘optimized supportive care for EVD’. In this context, pragmatic clinical training was integrated in routine ETC activities. Initial clinical manifestations of 13 confirmed EVD patients were similar to those of 276 patients with suspected, but subsequently non confirmed EVD. These patients suffered from other acute infections (e.g. malaria in 183 of 276 patients; 66%). Five of the 276 patients with suspected EVD died. One of these five patients had Lassa virus disease and a coronavirus disease 2019 (COVID-19) co-infection.

Conclusion: Multidisciplinary outbreak response teams can rapidly optimise ETC design. Trained clinical teams can provide WHO-recommended optimised supportive care, including safe administration of Ebola-specific monoclonal antibodies. Pragmatic training in essential critical care can be integrated in routine ETC activities.

Contribution: This article describes clinical realities associated with implementation of WHO-recommended standards of ‘optimized supportive care’ and administration of Ebola virus specific treatments. In this context, the importance of essential design principles of ETCs is underlined, which allow continuous visual contact and verbal interaction of health workers and families with their patients. Elements that may contribute to further quality of care improvements for patients with confirmed or suspected EVD are discussed.

Keywords: Zaire Ebolavirus disease essential emergency and critical care; referral pathways; Ebola-specific monoclonal antibodies; Ebola vaccination; Lassa virus disease.

Introduction

The most devastating Ebola epidemic to date occurred in West Africa between 2013 and 2016. More than 28 000 developed Zaire ebolavirus disease (EVD), and more than 11 000 died.1,2,3 Around 2500 of these deaths occurred in Guinea, the starting point of this epidemic.1,2,3

Since 2016, further Ebola outbreaks have occurred in the Democratic Republic of the Congo (DRC) and now Uganda.1 During this period, substantial advances have been made in introducing Ebola vaccines and improving the level of clinical care for EVD patients.1,4,5,6,7,8 Treatment provided in Ebola treatment centres (ETCs)9 during the Zaire ebolavirus epidemic in the eastern DRC (2018–2020) followed principles of ‘essential emergency and critical care (EECC)’ outlined in the World Health Organization (WHO) guidelines (‘optimized supportive care’).4,7,8,9,10 Additionally, in a randomised controlled trial (RCT; Pamoja Tulinde Maisha [PALM] trial) conducted in the DRC (2018–2019), administration of Ebola-specific monoclonal antibodies (mAb114, Ebanga; REGN-EB3, Inmazeb) was associated with lower mortality.6 Ebola virus disease patients presenting to an ETC early in their disease process with low viral load (VL) benefited from a care package of essential critical care and Ebola-specific treatment.4,6,7 Survival rates above 80% were reported in these patients.6

Optimised design of ETCs allows visibility of patients from the low-risk zone, which enables continuous monitoring and improved communication between clinical teams working in low- and high-risk zones. This configuration facilitates provision of essential critical care and psychological support for patients with confirmed or suspected EVD.5,9

At the end of the Ebola epidemic in West Africa (2013–2016), vaccinations were introduced as an essential part of a comprehensive outbreak response strategy combining preventive and therapeutic elements.1,11 All aspects of outbreak management are based on intensive community engagement.1

In February 2021, Guinea declared a further Zaire ebolavirus outbreak in a region (N’zérékoré) previously affected during the epidemic in 2013–2016.1,2,12,13 By the end of the outbreak in June 2021, 23 Ebola virus infections were reported (16 confirmed and 7 probable cases). Of these 23 patients, 11 survived and 12 died.12,13

In this series we describe 13 patients with confirmed EVD and 276 patients with suspected EVD treated in two ETCs, and their clinical outcomes.

Methods

The N’zérékoré region has a population of around 480 000 inhabitants, distributed over 11 subprefectures.14 At the end and after the Ebola epidemic in 2014–2016, centres de traitement épidémiologiques (CT_Epi) were established in several regions in Guinea and were designed to provide care for patients with highly infectious diseases (e.g. Ebola, Lassa, Cholera, COVID-19). As part of the outbreak response, clinical care for patients with confirmed or suspected EVD was provided in two Centres de Traitement Épidémiologique (CT-Epi or ETC), led by the Agence Nationale de Sécurité Sanitaire (ANSS), the outbreak response agency of the Guinean Ministry of Health (MOH).15 These two ETCs were located in two of the four subprefectures directly affected by the Ebola outbreak. Clinical care in ETCs was supported by the nongovernmental organisation Alliance for International Medical Action (ALIMA) and the WHO.12,16 Both CT-Epis or ETCs needed some adaptation to allow adequate care for patients with highly infectious diseases (HID; Figure 1).5,9

Figure 1: The setup of a modern-design Ebola treatment centre (ETC) and the chambre d’urgence biosécurisée pour épidémies or biosecure emergency rooms for epidemics (CUBE). Patients with confirmed or suspected Ebola virus disease are treated in single compartments (b, c). Each patient is visible from the low-risk zone. The CUBE (a) is of particular benefit for the treatment of critically ill patients and can be integrated rapidly in ETC setups as well as patient circuits of general health facilities.Pictures (b, c) from the DRC (2018–2020), with permission to print from Luca Fontana and Michele DiMarco (WHO).

In this series, data are reviewed from all patients with suspected or confirmed EVD hospitalised in the ETCs of N’zérékoré and Gouécké during the outbreak period (14 February 2021 – 19 June 2021).

Authorisation for publication

Authorisation for publication of data was given by Guinean health authorities.15 REGENERON-EB3 (REGN-EB3) was administered following WHO recommendations for treatment of Zaire ebolavirus disease.1,17,18 Care provided in ETCs followed international critical care strategies adapted to contexts of an Ebola outbreak in resource-limited settings.4,10,19,20 A pragmatic training programme in essential critical care integrated in routine ETC activities was designed to contribute to general capacity building.

Set-up of Ebola treatment centres and description of level of care provided

The ETC in the urban setting of N’zérékoré acted as a referral unit for all confirmed EVD patients, critically ill suspected cases and nonsevere direct admissions. This ETC had a capacity of 34 beds and three ‘Chambre d’Urgence Biosécurisée pour Epidémies [CUBE; biosecure emergency r ooms for epidemics]’ (see Figure 1).4,5 If necessary, two more CUBEs could have been set up rapidly to expand the critical care zone of the ETC.

The ETC located in Gouécké (54 km from N’zérékoré) was set up for the care of patients with suspected EVD. This unit had a capacity of 10 beds and two CUBEs. Competencies of the ETC team in Gouécké to provide prereferral management for critically ill patients with suspected EVD were strengthened. Referrals were conducted with ambulances, allowing basic care during transfer while maintaining recommended infection prevention measures.1 Competencies in patient transfer were strengthened. Communication channels between referring and receiving units as well as the outbreak coordination team were improved.

Newly designed ETCs suggested by WHO and partners allow continuous observation of confirmed or suspected EVD patients from the low-risk zone, either via simple windows (e.g. plexiglass) or via CUBEs (Figure 1).5,9 This setup allows constant interaction between patients, health workers and relatives. To prevent cross-infection, patients are placed in self-contained rooms (with toilet and shower). Additionally, patients with suspected or confirmed EVD are treated in separate sections of the ETC.

The CUBE is an innovative single treatment room for patients with HIDs, which was used extensively by ALIMA and partners in three ETCs during the Ebola epidemic in the DRC (2018–2020).5,16 These CUBEs can be deployed and integrated rapidly in ETCs as well as patient circuits of general health facilities to establish critical care zones during epidemics.5,9 The device allows continuous surveillance of critically ill patients with HIDs, while following biosecurity recommendations.1,5 Certain clinical interventions can be conducted from the low-risk zone, for example, vital sign monitoring, O2 administration, point-of-care ultrasound (POCUS) and adaptation of infusion settings.5,9 Clinical teams in the low-risk zone can coordinate activities with health workers entering the high-risk zone with personal protection equipment (PPE).5,9

Figure 2 describes the level of care (LOC) provided in the two ETCs in the N’zérékoré region, following WHO-EVD guidelines and international recommendations for context-adapted critical care.4,8,10,19,20 A similar LOC was established in ETCs during the Ebola outbreak in the DRC (2018–2020).7,16 Not all elements of this ‘care package’ could be established from the beginning of the outbreak in Guinea.

Figure 2: Simplified description of level of care provided in Ebola treatment centres in N’zérékoré (NZK) and Gouécké (Guinea 2021).

Blood bank and laboratory

Specific polymerase chain reaction (PCR) testing and VL analysis for Ebola virus were established in the regional hospital in N’zérékoré.12 On-demand coronavirus disease 2019 (COVID-19) PCR testing could be performed. Lassa and Marburg virus testing was included in the testing panel of patients with suspected EVD from the beginning of May 2021.43,44

The initial priority of the ETC laboratory team was to strengthen safe blood transfusion processes in collaboration with national transfusion services and the regional hospital. Later, during the Ebola outbreak, a small ETC laboratory was established using a modified CUBE, allowing rapid processing of blood samples (e.g. biochemistry, haemogram) by technicians working in the low-risk zone, while respecting biosecurity recommendations.

Capacity building

A training programme supported by a WHO advisor and a paediatrician with critical care experience (20 March 2021 to 20 April 2021) was integrated in routine ETC activities in N’zérékoré and Gouécké. The instructors (H.J.L. and M.L.) gained experience during previous Ebola outbreaks. Training materials were developed during the Ebola epidemic in the DRC (2018–2020) and reviewed for the outbreak in Guinea by specialists associated with the WHO, ALIMA and international partners (Several authors [R.K., H.J.L., M.L., A.M.C.] are part of the WHO-EVD guideline development team).18 Training content followed principles of essential critical care adapted to resource-limited contexts tailored to characteristics of EVD.4,8,10 Treatment of specific patient populations was integrated in the training, for example, obstetric emergencies, newborn and paediatric care. Training methods included ‘on-the-job’ coaching, tutorials, skills training, case discussions and clinical simulations integrating utilisation of the CUBE.5,9

Data collection and data analysis

Data were extracted from patient files, for example, gender, age, clinical presentation, treatment, clinical progress and available laboratory results. Clinical details documented in a database were categorised to describe organ dysfunction, potential acute or chronic co-infections (e.g. malaria, human immunodeficiency virus [HIV], tuberculosis [TB]) or underlying noncommunicable diseases (NCDs). The WHO EVD case definition served as a basis for clinical screening and symptom assessment.45

Stata 12 (StataCorp LLC, College Station, Texas, United States) was used for all descriptive analyses. In view of the small number of patients, no statistical analysis comparisons were performed.

Ethical considerations

This study describes a series of patients with confirmed or suspected Ebola virus disease (EVD). Described clinical management follows the WHO recommendations and international guidelines (important guidelines and recommendations are referenced). This is not an interventional study. A formal ethics committee was therefore not required.

The Guinean Ministry of Health (MOH) authorised the use of Ebola-specific monoclonal antibodies as recommended by the WHO, based on the outcomes of a randomised controlled trial (RCT) published in 2019 (relevant sources are referenced in the article).

Results

Sociodemographic description of patients

During the study period, 13 patients with EVD and 276 patients with suspected EVD were treated in two ETCs in the N’zérékoré region (Table 1). During the outbreak, 2 of the 16 confirmed EVD patients were not admitted to an ETC (one survivor and one death).12,13 One EVD patient was treated in an ETC in Conakry and survived.12,13 Of the 13 described EVD patients, the age range was 22–70 years; seven were female, including one pregnant woman. Four (31%) EVD patients were health workers.

TABLE 1: Sociodemographic description of Ebola virus disease patients and patients with suspected Ebola virus disease.
Clinical presentation of patients, treatment and outcomes

Among 10 of the 13 EVD patients, the following nonspecific symptoms were reported by the outbreak transfer team prior to ETC admission: fever, headache, diarrhoea and abdominal pain. Five EVD patients had a positive malaria rapid diagnostic test (MRDT; Table 2).

TABLE 2: Clinical signs and malaria rapid diagnostic test results in Ebola virus disease patients and patients with suspected Ebola virus disease.

Among the 276 patients with suspected but nonconfirmed EVD, the most frequent symptoms recorded by the transfer team were: fever (76%), fatigue (67%), headache (64%) and loss of appetite (58%). Sixty-six percent of suspected cases had a positive MRDT. Diarrhoea was recorded in only 15%.

Documentation of time between onset of symptoms and ETC admission was challenging because of its dependence on communication with patients or relatives during a potentially stressful admission process. A delay of up to three days was documented in two nonsurviving EVD patients (Table 3 and Online Appendix 148). One of these patients was pregnant (32–34 weeks’ gestation) and deteriorated rapidly after ETC admission.

TABLE 3: Characteristics of patients admitted to the Ebola treatment centres in N’zérékoré and Gouécké (confirmed and suspected Ebola virus disease).

All four nonsurviving EVD patients presented with multi-organ dysfunction and died within 48 h of ETC admission (Table 3 and Online Appendix 148). Two of these patients died within 6 h and 13 h after ETC arrival, respectively. Two of the nonsurvivors were 70 years old.

Viral load testing was established several days after declaration of the Ebola outbreak. Therefore, prognostically important VL results at the time of ETC admission6 are available in only eight of the 13 EVD patients (Table 3 and Online Appendix 148). Six of these patients survived. All six survivors with available VL results received REGN-EB3. Five of these had low VL (nucleoprotein [NP]-cycle-threshold [CT] > 22). One EVD survivor (EVD patient-8) had a relatively high VL (NP-CT:21). In two of the non-survivors VL results were available (both NP-CT:22).

Ebola-specific monoclonal antibodies were available 2 weeks after the start of the outbreak, explaining delays in administration of REGN-EB3 in seven EVD patients (Table 3 and Online Appendix 148). All eight REGN-EB3 recipients survived, as well as one patient who did not receive REGN-EB3 (EVD Patient 2; Online Appendix 148). Two EVD patients passed away before REGN-EB3 was available. In two EVD patients, vital organ functions could not be stabilised after ETC admission. As administration of monoclonal antibodies can be associated with hypersensitivity reactions and haemodynamic instability,1,46 clinical teams aimed to stabilise patients before administration of REGN-EB3.

Mean length of stay (LOS) of EVD patients was 12 days (± 9.7; interquartile range [IQR]: 2–21) versus 2 days (± 1 or [0.9]; IQR 2–3) for patients with suspected EVD. After exclusion of EVD, many of these patients were referred for further care to the regional hospital.

A multidisciplinary ETC team was able to provide essential critical care from the start of the outbreak response, for example, provision of O2, fluid management, treatment of acute bacterial co-infections or severe malaria, safe administration of Ebola-specific monoclonal antibodies. Subsequently, a training programme integrated in routine activities supported ETC teams to optimise context-adapted critical care, for example, efficient utilisation of the CUBE;5 basic noninvasive respiratory support; management of haemodynamic instability and initiation of low-dose vasopressors; essential management of acute kidney injury (AKI) and electrolyte abnormalities;10 and introduction of POCUS.

Transfer of biomedical equipment to N’zérékoré was challenging, and logisticians needed to define priorities (e.g. O2 concentrators were transferred before noninvasive respiratory support devices).

Improvement of blood bank services was an initial priority for the ETC laboratory team. Further laboratory services (e.g. biochemistry, haemogram) were established later during the outbreak. Biochemistry results are therefore only available for EVD Patient 13 (Online Appendix 148). However, this example underlines that AKI is a frequent complication in EVD.4,6 Laboratory results of this patient show further biochemical derangement: elevated transaminases, amylase, creatinine kinase and low albumin levels.

Importantly, PCR testing of a 23-year-old man with suspected, but nonconfirmed EVD revealed Lassa virus disease and a COVID-19 co-infection (Table 3 and Online Appendix 148).43 This patient presented with comparable symptoms to EVD patients. On Day 2, he left the ECT against medical advice. Three days later, he was re-admitted with signs of multi-organ dysfunction and died 24 h later (Online Appendix 148).

Community engagement

In order to build confidence in outbreak response efforts, communities needed particular support.12,47 In this context, family and community members were encouraged to regularly visit ETCs and directly witness the quality of patient care.5,9

Discussion

Implementation of comprehensive Ebola outbreak management allowing early identification of EVD patients, contact tracing and preventive measures (e.g. vaccinations) needs strong community engagement.1,12,16,47 Care of patients with suspected and confirmed EVD is best provided close to affected populations to facilitate early initiation of effective treatment and to improve population confidence in outbreak-response measures.16,47

During the Ebola outbreak in Guinea (2021), the peripheral ETC in Gouécké could provide essential care. Following prereferral management, critically ill patients with suspected EVD and all confirmed EVD patients were transferred to the ETC in N’zérékoré, where further essential critical care was provided and REGN-EB3 could be administered (Figure 2).6,10 Patient referral systems are important elements of critical care49 and need to be part of outbreak response preparations.

Nine of the 13 described EVD patients survived. All eight patients who received Ebola-specific monoclonal antibodies (REGN-EB3)6,46 survived. All eight REGN-EB3 recipients had stable vital organ functions at the time of drug administration. In the six REGN-EB3 recipients whose VL results were available, five had low VL (NP-CT > 22). One REGN-EB3 recipient with a relatively high VL (NP-CT:21) also survived. The five EVD patients who did not receive REGN-EB3 were either admitted before the medication was available and/or presented with multi-organ dysfunction on ETC arrival (Online Appendix 148). One patient who did not receive REGN-EB3 survived (EVD patient-2; no VL available).

While this series is too small to draw statistically significant conclusions, outcomes are consistent with results of the PALM trial conducted during the Ebola epidemic in the DRC (2018–2020). This trial reported survival above 80% among EVD patients with low VL (NP-CT > 22) benefiting from essential critical care and administration of Zaire ebolavirus-specific monoclonal antibodies.6 Results of a WHO-led guideline development group (published in August 2022) recommend the ‘treatment with either MAB114 or REG-EB3 for patients with confirmed Zaire ebolavirus disease and for neonates of unconfirmed EVD status, 7 days or younger, born to mothers with confirmed EVD’.17,18 Hence, storage and administration of Ebola-specific monoclonal antibodies need to be part of Ebola outbreak preparedness plans.

Supportive care of EVD patients, outlined in the WHO guidelines, follows general critical care principles aimed at rapid stabilisation of vital organ functions, while considering characteristics of EVD.3,4,10,19,20,50

In this series, at least four of the 13 EVD patients needed O2 therapy early during ETC admission and may have benefited from noninvasive respiratory support. Over 70% of Ebola patients treated in Europe or the United States required supplemental O2, noninvasive or invasive respiratory support during their illness.4

Different causes of respiratory dysfunction need to be considered in EVD, for example, acute viral or bacterial co-infections, acute respiratory distress syndrome (ARDS) potentially associated with EVD and/or severe co-infections, fluid overload and cardiac dysfunction.4,51 Additionally, the presence of TB and HIV-associated opportunistic infections needs to be evaluated. Different pathologies may co-exist.4

Reliable O2 supply using O2 concentrators and an adequate electricity system were established in the ETC in N’zérékoré following WHO recommendations.52,53

Ebola virus disease patients frequently present with haemodynamic instability associated with serious enteral fluid losses and sepsis-related complications,3,4 often requiring considerable intravenous fluid replacement. In this context, the use of electrolyte-balanced, isotonic resuscitation fluids may be particularly important.4,19,20,54

Training sessions integrated in routine practice enabled the ETC team in N’zérékoré to use basic noninvasive respiratory support as well as low-dose vasopressor infusions.10 Additionally, POCUS was introduced to guide haemodynamic stabilisation.38 Not all patients could benefit from these interventions (Figure 2 and Online Appendix 148), as training in these elements of essential critical care started in March 2021.

Three of the 13 EVD patients may have benefited from red blood cell (RBC) transfusions (Online Appendix 148). These three patients showed signs of haemorrhage associated with haemodynamic instability and died within 48 h of admission. Arranging an urgent RBC transfusion was challenging at the beginning of the Ebola outbreak, as the ETC was situated several km from the blood bank located in the regional hospital.

Five of the 13 EVD patients and 66% of patients with suspected EVD had positive malaria tests. As all Ebola outbreaks so far have occurred in malaria-endemic regions,1 malaria co-infections need to be anticipated as a cause of anaemia in EVD patients.37 Importantly, around 6% of patients with suspected EVD (16/276) required RBC transfusions in this study (Table 3).

Haemorrhage is an EVD complication that can occur during advanced stages of the disease process.3,4,55 Causes may include disseminated intravascular coagulation and hepatic injury.3,4 In this study, clinical signs of coagulopathy associated with haemodynamic instability were seen in three EVD patients. These patients did not survive (Online Appendix 148).

Besides RBC transfusions, options for provision of other blood products should be evaluated in low-resource settings, for example, fresh frozen plasma (FFP) or thrombocyte concentrates.4 Fresh dried plasma may be an alternative to provide coagulation factors in settings where production and storage of FFP are challenging.56

Developing safe transfusion services was a priority of the ETC laboratory team. Biosecurity measures were established in cooperation with Guinean transfusion services. International and national guidelines for the setup of transfusion services are important elements of outbreak preparedness.

Treatment of neurological emergencies in EVD patients presenting with altered mental status, focal neurological signs or seizures follows essential critical care principles: respiratory and cardiovascular functions need to be stabilised.4,8,10 Hypoglycaemia occurs frequently in EVD patients, requiring careful surveillance of blood sugar levels.3,4,10

Potential severe co-infections (e.g. bacterial meningitis, severe malaria) need to be treated.3,4,10,37 Ebola virus infections can have a direct central nervous system impact, while neurological complications associated with coagulopathies, electrolyte imbalances, renal or hepatic failure need to be considered.3,4,8

In the management of status epilepticus refractory to first-line antiseizure medication (ASM), injectable levetiracetam can be of particular benefit in the care of EVD patients or other HIDs. Injectable levetiracetam administration is simple and not associated with severe cardiorespiratory side effects.24,25,26 Even when treating EVD patients in CUBEs,5 immediate initiation of emergency interventions can be challenging. Additionally, mechanical ventilation is not a feasible option in many resource-limited contexts. Therefore, it may be beneficial to replace ASM with potential cardiorespiratory side effects (e.g. phenobarbitone and phenytoin) with ASM with a better side effect profile.

Acute kidney injury, electrolyte abnormalities as well as acid–base abnormalities are common complications in EVD.3,4 Raised creatinine levels are associated with an elevated mortality risk.4,6,50 Signs of rhabdomyolysis (elevated creatinine kinase), frequently seen in EVD patients, may contribute to renal dysfunction.3,4 This series emphasises the importance of essential AKI management in contexts without ability to initiate renal replacement therapy (Figure 2).8,10,30

Elevation of transaminases, amylase and low albumin levels are further biochemistry abnormalities frequently observed in EVD or Lassa virus disease.3,4,8,10,57

Malaria co-infections are common among EVD patients treated in malaria-endemic regions and need to be managed urgently.3,37 Early initiation of efficient antibiotic treatment for potential bacterial co-infections is equally important.3,4,6,8,10

Nutritional support is an essential element in EVD care.29 A proactive approach to enteral nutrition in critically ill EVD patients should follow principles of existing international guidelines.27,28 Importantly, the WHO has published EVD guidelines for pregnant and breastfeeding women.34

Optimised ETC design facilitates provision of optimised supportive care and prevention of cross-infection.4,5,9 All patients with suspected or confirmed EVD need to be visible from the low-risk zone, allowing continuous surveillance.5,9 In this context, the CUBE provides an innovative interface between health workers positioned in the low-risk zone, patients with confirmed or suspected EVD and clinicians working in the high-risk zone.5 Additionally, optimised ETC design facilitates psychological support for children and adults as well as provision of palliative care for patients with end-stage critical illness.5,9 Furthermore, the visibility of ETC care promotes trust among populations affected by Ebola epidemics: ‘Newly designed ETCs are not simple isolation units but are treatment units built around needs of patients, staff, families and communities (WHO)’.5,9 Experience gained in ETC design can be used in the management of other HID outbreaks.5,9,57,58,59 In this context, the WHO and the World Food Program (WFP) initiated a design process for a mobile, rapidly deployable ‘infectious disease treatment module’.60

Four of the 13 EVD patients treated in N’zérékoré were health workers, which confirms experience from previous Ebola outbreaks indicating a considerable infection risk during patient care in regular health facilities.1,61 In regions potentially affected by Ebola epidemics, health workers therefore need to be vaccinated and safe working environments need to be established.1,12,61 Importantly, a recent publication describes postexposure prophylaxis after high-risk contacts using Ebola-specific monoclonal antibodies.42

In agreement with larger studies, this series suggests that initial EVD symptoms are similar to early manifestations of common acute infections (e.g. malaria).3,55,62 The WHO Ebola case definition therefore has limited specificity, especially in the early phase of a disease outbreak.4,45,55,62,63 In this context, screening and triage processes should be strengthened in regular health facilities.33,59,64 As signs of EVD or other HIDs may not always be identified during the admission process, HID risk assessment needs to continue during routine inpatient care.

Treatment units with limited bed capacity for patients with suspected HID can be integrated in patient circuits of emergency departments of regular health facilities. Efficient laboratory capacities are needed to guarantee rapid exclusion or confirmation of HIDs.12,65 Rapid outbreak response support for these decentralised treatment units could be triggered by the confirmation of HID and/or increasing numbers of patients with suspected HIDs. Rapidly deployable treatment units for HID can be of value in this context.60,66

Lassa virus disease was detected in one patient with suspected but nonconfirmed EVD. This patient had clinical and biochemical characteristics similar to EVD patients (Online Appendix 148).3,4,43 Acute kidney injury was the predominant organ dysfunction in this patient, accompanied by elevated transaminases and signs of rhabdomyolysis, which then progressed to terminal multi-organ failure (MOF).43 It can only be speculated if a COVID-19 co-infection contributed to this patient’s MOF.43

Lassa virus disease is endemic in certain regions in West Africa, including Guinea.67,68,69 Additionally, in August 2021, the Guinean MOH reported a case of Marburg virus disease (MVD) in the prefecture of the Guéckédou–N’zérékoré region.44 These findings emphasise that surveillance and outbreak response systems in West Africa need to prepare for a range of HIDs.12,65

Among 681 EVD patients recruited in the PALM trial (DRC; 2018–2019), 25% patients were younger than 18 years and almost 13% younger than 5 years.6 In this series, the mean age of EVD patients was around 46 years (Figure 2). It can be speculated that during the Ebola outbreak in Guinea (2021), initially adults were infected, while transmission to a wider spectrum of the population could be prevented by control measures (e.g. vaccinations).12

Many patients (38%) with suspected EVD reported in this study were 15 years or younger (17% were 5 years or younger), highlighting that ETCs need to prepare for medical and psychological needs of children and adolescents.32,35

One of the 13 described EVD patients was pregnant. She presented 2 days after onset of symptoms with multi-organ dysfunction (NP-CT:22), and despite initiation of essential critical care, she died around 6 h after ETC admission.

Previous reviews report high mortality rates among pregnant EVD patients.34 Experiences from the Ebola outbreak in the DRC (2018–2020) emphasise that referral pathways and ETCs need to be prepared for rapid initiation of treatment for pregnant women, including essential critical care, early administration of Ebola-specific monoclonal antibodies,1,34 normal and instrumental deliveries, caesarean sections and obstetric emergencies (e.g. postpartum haemorrhage and eclampsia).34 Additionally, ETCs need to be set up for essential newborn resuscitation and care.32,33

A family accommodation (‘crèche’) needs to be part of ETC design, offering care for children of EVD patients as well as rehabilitation for surviving mothers and children.9,32,34,35,41 Furthermore, the WHO recommends programmes for Ebola survivors designed to address medical and psychosocial challenges and to reduce risk of further Ebola virus transmission (e.g. sexual transmission).34,41

Health services in Guinea face considerable challenges (e.g. maternal and child health).70,71 As a result of the Ebola epidemic in West Africa (2014–2016), a substantial impact on general health services was documented.72 Therefore, comprehensive outbreak strategies should support efforts to build resilient health systems in epidemic-affected regions.72

Limitations of the study

Interpretations of study results are limited by the small number of EVD patients. Provision and documentation of clinical care in ETCs is challenging. However, essential critical care could be provided from the start of the outbreak. Further elements of context-adapted critical care, including provision of REGN-EB3 as well as laboratory services, were progressively strengthened. The clinical progress of patients with suspected but subsequently nonconfirmed EVD could only be monitored until discharge from the ETC.

Conclusion

Multidisciplinary outbreak response teams can rapidly set up well-designed ETCs close to affected populations. Trained clinical teams can provide optimised supportive care, including safe administration of Ebola-specific monoclonal antibodies, as recommended by the WHO. Pragmatic training in essential critical care integrated in routine ETC activities contributed to capacity building.

The results of this series indicate that initial symptoms of EVD are often nonspecific. One patient with suspected EVD had Lassa virus disease, highlighting the importance of considering differential diagnoses during Ebola outbreaks based on regional epidemiology.

Acknowledgements

We thank all members of the multidisciplinary outbreak management team as well as the remarkable clinical and nonclinical health professionals working in the region affected by the Ebola outbreak for their dedication and courage. We would like to particularly highlight the excellent work of the senior nurses Justin Kolie (Guinea, ALIMA) and Francois Kamona (Democratic Republic of the Congo, ALIMA) who supported coordination and clinical work in the ETCs in Gouécké and N’zérékoré. The logisticians Mamadi Camara (Guinea, ALIMA) and Mamadou Madi (Niger, ALIMA) played an essential role in optimising processes in the ETCs.

We highly acknowledge all community members facilitating the outbreak response. Among these, we would like to particularly mention the Ebola survivors who supported outbreak response teams in Ebola treatment centres and communities.

Our thoughts are with the victims of the Ebola outbreak, their families, as well as all the patients who suffered indirectly by the fact that the Ebola outbreak affected routine health services.

Competing interests

The authors declare that they have no financial or personal relationships that may have inappropriately influenced them in writing this article.

Authors’ contributions

B.C.P., A.M.C., P.L., R.K. and H.-J.L. conceived the idea and designed the study. A.M.C., A.C., M.K., K.E., M.S.C., J.B.T., L.A., M.L.C.-R., B.S. and H.-J.L. investigated the cases. B.C.P., A.M.C., A.C., M.K., M.S.C. and J.B.T. collected the data. B.C.P. and H.-J.L. analysed the data. B.C.P., A.M.C., A.C., M.K., K.E., M.S.C., L.A., S.S., E.B.d.S.F., P.L., N.M., M.L.C.-R., B.S., M.S.C., A.H.B., D.M., J.B.T., R.K. and H.-J.L. interpreted the data. B.C.P. and H.-J.L. wrote the first draft. B.C.P., A.M.C., K.E., S.S., E.B.d.S.F., N.M., P.L., B.S., M.L.C.-R., B.M., R.K. and H.-J.L. critically reviewed the manuscript. All the authors have read and approved the final version of the manuscript.

Funding information

This research received no specific grant from any funding agency in the public, commercial or not-for-profit sectors.

Data availability

Anonymised patient data and data analysis are available on demand. Project management information are available on the websites of the WHO, the Guinean Ministry of Health and the nongovernmental organisation ALIMA. These websites are referenced in this article.

Patient data protection follows the regulations of the Guinean Ministry of Health and international data protection guidelines.

Disclaimer

The views and opinions expressed in this article are those of the authors and do not necessarily reflect the official policy or position of any affiliated agency of the authors.

References

  1. WHO. Ebola viral disease; key facts [homepage on the Internet]. 2021 [cited 2023 Jan 05]. Available from: https://www.who.int/news-room/fact-sheets/detail/ebola-virus-disease
  2. Agua-Agum J, Allegranzi B, Ariyarajah A, et al. After Ebola in West Africa – Unpredictable risks, preventable epidemics. N Engl J Med. 2016;375(6):587–596. https://doi.org/10.1056/NEJMsr1513109
  3. Jacob ST, Crozier I, Fischer WA, et al. Ebola virus disease. Nat Rev Dis Primers. 2020;6(1):13. https://doi.org/10.1038/s41572-020-0147-3
  4. Kiiza P, Mullin S, Teo K, Adhikari NKJ, Fowler RA. Treatment of Ebola-related critical illness. Intensive Care Med. 2020;46(2):285–297. https://doi.org/10.1007/s00134-020-05949-z
  5. ALIMA. CUBE: The biosecure emergency care unit [homepage on the Internet]. 2021 [cited 2023 June 06]. Available from: https://alima.ngo/en/cube/
  6. Mulangu S, Dodd LE, Davey RT, Jr, et al. A randomized, controlled trial of Ebola virus disease therapeutics. N Engl J Med. 2019;381(24):2293–2303. https://doi.org/10.1056/NEJMoa1910993
  7. Fischer WA, 2nd, Crozier I, Bausch DG, et al. Shifting the paradigm – Applying universal standards of care to Ebola virus disease. N Engl J Med. 2019;380(15): 1389–1391. https://doi.org/10.1056/NEJMp1817070
  8. Lamontagne F, Fowler RA, Adhikari NK, et al. Evidence-based guidelines for supportive care of patients with Ebola virus disease. Lancet. 2018;391(10121): 700–708. https://doi.org/10.1016/S0140-6736(17)31795-6
  9. WHO. Ebola: Clinical management and operations unit [homepage on the Internet]. 2022 [cited 2022 Oct 04]. Available from: https://www.who.int/teams/health-care-readiness/ebola-clinical-management
  10. WHO. Optimized supportive care for Ebola virus disease; Clinical management standard operating procedures [homepage on the Internet]. 2019 [cited 2022 Oct 05]. Available from: https://www.who.int/publications/i/item/optimized-supportive-care-for-ebola-virus-disease
  11. WHO. Major milestone for WHO-supported Ebola vaccine [homepage on the Internet]. 2019 [cited 2022 Aug 27]. Available from: https://www.who.int/news/item/18-10-2019-major-milestone-for-who-supported-ebola-vaccine
  12. WHO. Ebola – Guinea [homepage on the Internet]. 2021 [cited 2022 Mar 04]. Available from: https://www.who.int/emergencies/disease-outbreak-news/item/2021-DON328
  13. MOH-Guinea, OCHA. Ministére de la santé-Guinée : Rapport de situation n°126 sur l’épidémie de la Maladie à Virus Ebola (MVE) – 19 Juin 2021; et rapports précédents [homepage on the Internet]. 2021 [cited 2022 Mar 17]. Available from: https://www.humanitarianresponse.info/en/operations/guinea/documents/document-type/situation-report
  14. Guinée INdlSI. Institut National de la Statistique (INS); Population de la Guinée [homepage on the Internet]. 2021 [cited 2022 Mar 27]. Available from: https://www.stat-guinee.org/
  15. ANSS. Agence nationale de sécurité sanitaire (Guinée, Conakry) [homepage on the Internet]. 2022 [cited 2022 Mar 27]. Available from: https://www.anss-guinee.org/
  16. ALIMA. Alliance for International Medical Action (ALIMA) – Ebola [homepage on the Internet]. 2021 [cited 2021 Jan 20]. Available from: https://alima.ngo/en/tag/ebola-en/
  17. Gao Y, Zhao Y, Guyatt G, et al. Effects of therapies for Ebola virus disease: A systematic review and network meta-analysis. Lancet Microbe. 2022;3(9):E683–E692. https://doi.org/10.1016/S2666-5247(22)00123-9
  18. WHO. Therapeutics for Ebola virus disease [homepage on the Internet]. 2022 [cited 2022 Sept 12]. Available from: https://www.who.int/publications/i/item/9789240055742
  19. Surviving-sepsis-campaign. Surviving sepsis campaign: Pediatric patients [homepage on the Internet]. 2021 [cited 2022 Feb 10]. Available from: https://www.sccm.org/SurvivingSepsisCampaign/Guidelines/Pediatric-Patients
  20. SSC. Surviving Sepsis campaign 2021; Adult guidelines [homepage on the Internet]. 2021 [cited 2022 Feb 10]. Available from: https://www.sccm.org/SurvivingSepsisCampaign/Guidelines/Adult-Patients
  21. Chisti MJ, Salam MA, Smith JH, et al. Bubble continuous positive airway pressure for children with severe pneumonia and hypoxaemia in Bangladesh: An open, randomised controlled trial. Lancet. 2015;386(9998):1057–1065. https://doi.org/10.1016/S0140-6736(15)60249-5
  22. Kneyber MCJ, De Luca D, Calderini E, et al. Recommendations for mechanical ventilation of critically ill children from the Paediatric Mechanical Ventilation Consensus Conference (PEMVECC). Intensive Care Med. 2017;43(12):1764–1780. https://doi.org/10.1007/s00134-017-4920-z
  23. Mer M, Schultz MJ, Adhikari NK, European Society of Intensive Care Medicine Global Intensive Care Working G, the Mahidol-Oxford Research Unit BT. Core elements of general supportive care for patients with sepsis and septic shock in resource-limited settings. Intensive Care Med. 2017;43(11):1690–1694. https://doi.org/10.1007/s00134-017-4831-z
  24. Chamberlain JM, Kapur J, Shinnar S, et al. Efficacy of levetiracetam, fosphenytoin, and valproate for established status epilepticus by age group (ESETT): A double-blind, responsive-adaptive, randomised controlled trial. Lancet. 2020;395(10231):1217–1224. https://doi.org/10.1016/S0140-6736(20)30611-5
  25. Lyttle MD, Rainford NEA, Gamble C, et al. Levetiracetam versus phenytoin for second-line treatment of paediatric convulsive status epilepticus (EcLiPSE): A multicentre, open-label, randomised trial. Lancet. 2019;393(10186):2125–2134. https://doi.org/10.1016/S0140-6736(19)30724-X
  26. Dalziel SR, Borland ML, Furyk J, et al. Levetiracetam versus phenytoin for second-line treatment of convulsive status epilepticus in children (ConSEPT): An open-label, multicentre, randomised controlled trial. Lancet. 2019;393(10186):2135–2145. https://doi.org/10.1016/S0140-6736(19)30722-6
  27. Tume LN, Valla FV, Joosten K, et al. Nutritional support for children during critical illness: European Society of Pediatric and Neonatal Intensive Care (ESPNIC) metabolism, endocrine and nutrition section position statement and clinical recommendations. Intensive Care Med. 2020;46(3):411–425. https://doi.org/10.1007/s00134-019-05922-5
  28. Van Zanten ARH, De Waele E, Wischmeyer PE. Nutrition therapy and critical illness: Practical guidance for the ICU, post-ICU, and long-term convalescence phases. Crit Care. 2019;23(1):368. https://doi.org/10.1186/s13054-019-2657-5
  29. WHO. Nutritional care of children and adults with Ebola virus disease in treatment centres [homepage on the Internet]. 2021 [cited 2021 Dec 30]. Available from: https://www.who.int/elena/titles/full_recommendations/nutrition_ebola/en/
  30. Goldstein SL. Urine output assessment in acute kidney injury: The cheapest and most impactful biomarker. Front Pediatr. 2019;7:565. https://doi.org/10.3389/fped.2019.00565
  31. BNF. British National Formula (BNF) [homepage on the Internet]. 2021 [cited 2021 Dec 31]. Available from: https://www.bnf.org/
  32. WHO. Standards for improving the quality of care for small and sick newborns in health facilities [homepage on the Internet]. 2020 [cited 2020 Dec 25]. Available from: https://www.who.int/publications/i/item/9789240010765
  33. WHO. Pocket book of hospital care for children: Guidelines for the management of common childhood illnesses [homepage on the Internet]. 2013 [cited 2022 Feb 26]. Available from: https://www.who.int/publications/i/item/978-92-4-154837-3
  34. WHO. Guidelines for the management of pregnant and breastfeeding women in the context of Ebola virus disease [homepage on the Internet]. 2020 [cited 2021 Aug 26]. Available from: https://www.who.int/publications/i/item/9789240001381
  35. WHO. Standards for improving the quality of care for children and young adolescents in health facilities [homepage on the Internet]. 2018 [cited 2022 Feb 26]. Available from: https://www.who.int/publications/i/item/9789241565554
  36. WHO. Guideline: Updates on paediatric emergency triage, assessment and treatment: Care of critically-ill children [homepage on the Internet]. World Health Organization; 2016 [cited 2023 Jan 05]. Available from: https://apps.who.int/iris/bitstream/handle/10665/204463/9789241510219_eng.pdf?sequence=1
  37. WHO. WHO Guidelines for malaria [homepage on the Internet]. World Health Organization; 2021 [cited 2021 June 06]. Available from: https://www.who.int/publications/i/item/guidelines-for-malaria
  38. Singh Y, Tissot C, Fraga MV, et al. International evidence-based guidelines on Point of Care Ultrasound (POCUS) for critically ill neonates and children issued by the POCUS Working Group of the European Society of Paediatric and Neonatal Intensive Care (ESPNIC). Crit Care. 2020;24(1):65. https://doi.org/10.1186/s13054-020-2787-9
  39. Nadimpalii A, Tsung JW, Sanchez R, et al. Feasibility of training clinical officers in point-of-care ultrasound for pediatric respiratory diseases in Aweil, South Sudan. Am J Trop Med Hyg. 2019;101(3):689–695. https://doi.org/10.4269/ajtmh.18-0745
  40. WHO. Palliative care [homepage on the Internet]. 2020 [cited 2021 Jan 02]. Available from: https://www.who.int/health-topics/palliative-care
  41. WHO. Clinical care for survivors of Ebola virus disease; interim guidance [homepage on the Internet]. 2016 [cited 2021 Aug 27]. Available from: https://www.who.int/publications/i/item/WHO-EVD-OHE-PED-16.1
  42. Jaspard M, Juchet S, Serra B, et al. Post-exposure prophylaxis following high-risk contact with Ebola virus, using immunotherapies with monoclonal antibodies, in the eastern Democratic Republic of the Congo: an emergency use program. Int J Infect Dis. 2021;113:166–167. https://doi.org/10.1016/j.ijid.2021.09.053
  43. Keita M, Cherif MS, Sivahera B, et al. Case report: COVID-19 and Lassa fever coinfection in an Ebola suspected patient in Guinea. Am J Trop Med Hyg. 2022;106(4):1094–1097. https://doi.org/10.4269/ajtmh.21-0713
  44. WHO. Marburg virus disease – Guinea [homepage on the Internet]. 2021 [cited 2022 March 03]. Available from: https://www.who.int/emergencies/disease-outbreak-news/item/marburg-virus-disease---guinea
  45. WHO. Case definition recommendations for Ebola or Marburg virus diseases: Interim guideline [homepage on the Internet]. 2014 [cited 2021 Aug 27]. Available from: https://apps.who.int/iris/handle/10665/146397?search-result=true&query=ebola+case+definition&scope=&rpp=10&sort_by=score&order=desc
  46. Regeneron. INMAZEB™; (ATOLTIVIMAB, MAFTIVIMAB, AND ODESIVIMAB-EBGN) injection [homepage on the Internet]. 2020 [cited 2022 Feb 21]. Available from: https://www.regeneron.com/downloads/inmazeb_fpi.pdf
  47. Frédéric LM, Saez M. Institute de recherche pour le développement (IRD): Etude de la résurgence de la maladie à virus Ebola dans la région de Nzérékoré: Rapport final [homepage on the Internet]. 2021. Available from: https://www.documentation.ird.fr/hor/fdi:010082904
  48. KDIGO. The 2012 kidney disease: Improving Global Outcomes (KDIGO) clinical practice guideline for acute kidney injury (AKI) [homepage on the Internet]. 2021 [cited 2021 July 05]. Available from: https://kdigo.org/guidelines/acute-kidney-injury/
  49. Reynolds TA, Sawe H, Rubiano AM, Shin SD, Wallis L, Mock CN. Strengthening health systems to provide emergency care. In: Jamison DT, Gelband H, Horton S, et al., editors. Disease control priorities: Improving health and reducing poverty. Washington, DC: The International Bank for Reconstruction and Development / The World Bank; 2017, pp. 247–265.
  50. Jaspard M, Mulangu S, Juchet S, et al. Development of the PREDS score to predict in-hospital mortality of patients with Ebola virus disease under advanced supportive care: Results from the EVISTA cohort in the Democratic Republic of the Congo. EClinicalMedicine. 2022;54:101699. https://doi.org/10.1016/j.eclinm.2022.101699.
  51. Riviello ED, Kiviri W, Twagirumugabe T, et al. Hospital incidence and outcomes of the acute respiratory distress syndrome using the Kigali modification of the Berlin definition. Am J Respir Crit Care Med. 2016;193(1):52–59. https://doi.org/10.1164/rccm.201503-0584OC
  52. WHO-UNICEF. WHO-UNICEF technical specifications and guidance for oxygen therapy devices [homepage on the Internet]. 2019 [cited 2021 Sept 16]. Available from: https://apps.who.int/iris/handle/10665/329874
  53. WHO. WHO technical consultation on oxygen access scale-up for COVID-19 [homepage on the Internet]. 2021 [cited 2021 July 20]. Available from: https://www.who.int/publications/i/item/9789240031517
  54. Levin M, Cunnington AJ, Wilson C, et al. Effects of saline or albumin fluid bolus in resuscitation: evidence from re-analysis of the FEAST trial. Lancet Respir Med. 2019;7(7):581–593. https://doi.org/10.1016/S2213-2600(19)30114-6
  55. Nsio J, Ardiet DL, Coulborn RM, et al. Differential symptomology of possible and confirmed Ebola virus disease infection in the Democratic Republic of the Congo: A retrospective cohort study. Lancet Infect Dis. 2022;23(1):91–102. https://doi.org/10.1016/S1473-3099(22)00584-9
  56. Mok G, Hoang R, Khan MW, et al. Freeze-dried plasma for major trauma – Systematic review and meta-analysis. J Trauma Acute Care Surg. 2021;90(3):589–602. https://doi.org/10.1097/TA.0000000000003012
  57. Duvignaud A, Jaspard M, Etafo IC, et al. Lassa fever outcomes and prognostic factors in Nigeria (LASCOPE): A prospective cohort study. Lancet Global Health. 2021;9(4):e469–e478. https://doi.org/10.1016/S2214-109X(20)30518-0
  58. Baker T, Schell CO, Petersen DB, et al. Essential care of critical illness must not be forgotten in the COVID-19 pandemic. Lancet. 2020;395(10232):1253–1254. https://doi.org/10.1016/S0140-6736(20)30793-5
  59. WHO. Severe acute respiratory infections treatment centre [homepage on the Internet]. 2021 [cited 2021 June 06]. Available from: https://www.who.int/publications/i/item/10665-331603
  60. WHO-WFP. INITIATE2 [homepage on the Internet]. 2022 [cited 2022 Sept 18]. Available from: https://www.who.int/initiatives/initiate2
  61. Baller A, Padoveze MC, Mirindi P, et al. Ebola virus disease nosocomial infections in the Democratic Republic of the Congo: A descriptive study of cases during the 2018–2020 outbreak. Int J Infect Dis. 2022;115:126–133. https://doi.org/10.1016/j.ijid.2021.11.039
  62. Lado M, Walker NF, Baker P, et al. Clinical features of patients isolated for suspected Ebola virus disease at Connaught Hospital, Freetown, Sierra Leone: A retrospective cohort study. Lancet Infect Dis. 2015;15(9):1024–1033. https://doi.org/10.1016/S1473-3099(15)00137-1
  63. Caleo G, Theocharaki F, Lokuge K, et al. Clinical and epidemiological performance of WHO Ebola case definitions: A systematic review and meta-analysis. Lancet Infect Dis. 2020;20(11):1324–1338. https://doi.org/10.1016/S1473-3099(20)30193-6
  64. WHO. Interagency triage tool [homepage on the Internet]. 2020 [cited 2020 May 25]. Available from: https://www.who.int/publications-detail/clinical-care-of-severe-acute-respiratory-infections-tool-kit
  65. WHO. Integrated Disease Surveillance and Response (IDSR) technical guidelines [homepage on the Internet]. 2019 [cited 2022 Mar 03]. Available from: https://www.afro.who.int/publications/technical-guidelines-integrated-disease-surveillance-and-response-african-region-third
  66. Lang HJ, Fontana L, Lado M, Kojan R. Triage of patients with Ebola virus disease. Lancet Infect Dis. 2022;23(1):10–12. https://doi.org/10.1016/S1473-3099(22)00721-6
  67. WHO. Lassa fever [homepage on the Internet]. 2017 [cited 2022 Mar 03]. Available from: https://www.who.int/news-room/fact-sheets/detail/lassa-fever
  68. Mylne AQ, Pigott DM, Longbottom J, et al. Mapping the zoonotic niche of Lassa fever in Africa. Trans R Soc Trop Med Hyg. 2015;109(8):483–492. https://doi.org/10.1093/trstmh/trv047
  69. Kernéis S, Koivogui L, Magassouba N, et al. Prevalence and risk factors of Lassa seropositivity in inhabitants of the forest region of Guinea: A cross-sectional study. PLoS Negl Trop Dis. 2009;3(11):e548. https://doi.org/10.1371/journal.pntd.0000548
  70. WHO. Maternal mortality: Key facts [homepage on the Internet]. 2019 [cited 2022 Mar 12]. Available from: https://www.who.int/news-room/fact-sheets/detail/maternal-mortality
  71. UN/Inter-Agency-Group. Levels & trends child mortality; Report 2021: UN inter-agency group for child mortality estimation [homepage on the Internet]. 2021 [cited 2022 June 30]. Available from: https://childmortality.org/reports
  72. WHO. Scoping review of interventions to maintain essential services for maternal, newborn, child and adolescent health and older people during disruptive events [homepage on the Internet]. 2021 [cited 2021 Jan 24]. Available from: https://www.who.int/publications/i/item/9789240038318


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