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A Landscape Analysis of Pediatric and Congenital Heart Disease Services in Africa

Published online by Cambridge University Press:  27 August 2025

Thomas Aldersley Open the ORCID record for Thomas Aldersley [Opens in a new window] ,
Sulafa Ali ,
Adila Dawood ,
Frank Edwin ,
Kathy Jenkins ,
Alexia Joachim ,
John Lawrenson ,
Darshan Reddy ,
Drissi Boumzebra  and
James D. St. Louis Open the ORCID record for James D. St. Louis [Opens in a new window]
...Show all authors
Thomas Aldersley
Affiliation:
Department of Paediatrics, University of Cape Town, Cape Town, South Africa
Sulafa Ali
Affiliation:
Division of Pediatric Cardiology, University of Khartoum, Khartoum, Sudan
Adila Dawood
Affiliation:
Department of Paediatrics, University of Cape Town, Cape Town, South Africa
Frank Edwin
Affiliation:
Division of Cardiothoracic Surgery, University of Health and Allied Sciences, Ho, Ghana
Kathy Jenkins
Affiliation:
Department of Cardiology, Harvard Medical School, Department of Pediatrics, Boston Children’s Hospital, Boston, MA, USA
Alexia Joachim
Affiliation:
Department of Paediatrics, University of Cape Town, Cape Town, South Africa
John Lawrenson
Affiliation:
Department of Paediatrics, University of Cape Town, Cape Town, South Africa Department of Paediatrics, Stellenbosch University, Stellenbosch, South Africa
Darshan Reddy
Affiliation:
Division of Cardiothoracic Surgery, University of Kwa-Zulu Natal, Durban, South Africa
Drissi Boumzebra
Affiliation:
Department of Cardiovascular Surgery, Mohamed VI University Hospital, Marrakech, Morocco
James D. St. Louis
Affiliation:
Department of Surgery, Augusta University, Augusta, GA, USA
Christo Tchervenkov
Affiliation:
Division of Pediatric Cardiovascular Surgery, McGill University, Montreal, Canada
Amy Verstappen
Affiliation:
Global Arch, Windsor, CT, USA
Bistra Zheleva
Affiliation:
Children’s Heart Link, Minneapolis, MN, USA
Liesl Zühlke*
Affiliation:
Department of Paediatrics, University of Cape Town, Cape Town, South Africa South African Medical Research Council, Cape Town, South Africa
*
Corresponding author: Liesl Zühlke; Email: liesl.zuhlke@mrc.ac.za
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Abstract

Background:

There is geographic disparity in the provision of Pediatric and Congenital Heart Disease (PCHD) services; Africa accounts for only 1% of global cardiothoracic surgical capacity. Methods: We conducted a survey of PCHD services in Africa, to investigate institution and national-level resources for pediatric cardiology and cardiothoracic surgery. Results were compared with international guidelines for PCHD services and institutions were ranked by a composite score for low- and middle-income PCHD services. Results: There were 124 respondents from 96 institutions in 45 countries. Eighteen (40%) countries provided a full PCHD service including interventional cardiology and cardiopulmonary bypass (CPB) cardiac surgery. Ten countries (22%) provided cardiac surgery services but no interventional cardiology service, 4 of which did not have CPB facilities. One provided interventional cardiology services but no cardiac surgery service. Ten countries (22%) had no PCHD service. There were 0.04 (interquartile range [IQR]: 0.00-0.13) pediatric cardiothoracic surgeons and 0.17 (IQR: 0.02-0.35) pediatric cardiologists per million population. No institution met all criteria for level 5 PCHD national referral centers, and 8/87 (9.2%) met the criteria for level 4 regional referral centers. Thirteen (29%) countries report both pediatric cardiology and cardiothoracic surgery fellowship training programs. Conclusions: Only 18 (40%) countries provided full PCHD services. The number of pediatric cardiologists and cardiothoracic surgeons is below international recommendations. Only Libya and Mauritius have the recommended 2 pediatric cardiologists per million population, and no country meets the recommended 1.25 cardiothoracic surgeons per million. There is a significant shortage of fellowship training programs which must be addressed if PCHD capacity is to be increased.

Keywords

pediatriccardiologycardiac surgeryglobal healthhealth infrastructureservicesAfricasurvey

Information

Type
Review
Information
Cardiology in the Young , Volume 35 , Issue 9 , September 2025 , pp. 1782 - 1791
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Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (https://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
© The Author(s), 2025. Published by Cambridge University Press

Introduction

There is geographic disparity in the provision of Pediatric and Congenital Heart Disease (PCHD) services. Previous studies show that North America and Western Europe account for 74% of the world’s cardiothoracic surgical capacity. Africa, however, accounts for only 1% of the total global capacity. Reference Vervoort, Meuris, Meyns and Verbrugghe1 This translates to geographic disparities in outcomes for congenital (CHD) and rheumatic heart diseases (RHD). For example, globally RHD deaths have decreased by 15.6% since 1990. Reference Ou, Yu and Liang2 In low-income and middle-income countries (LMICs), however, there was a 23.75% and 7.07% increase in RHD deaths over the same period, respectively. Reference Ou, Yu and Liang2 Similarly, CHD caused 261 247 deaths globally in 2017, a reduction of 34.5% (95% uncertainty interval: 19.8-44.6) since 1990. 3 However, CHD mortalities decreased by only 20.1% in southern sub-Saharan Africa, and actually increased for all other sub-Saharan regions, with mortalities in Central and Western sub-Saharan Africa increasing by 38.1% and 40.3%, respectively. 3 These disparities underscore the urgent need to improve PCHD services in Africa and other low- and middle-income settings. To achieve this, we must first understand what level of services currently exists in relation to established PCHD guidelines.

Pediatric and Congenital Heart Disease center guidelines vary depending on their geographic focus, primary medical field, conceptual framework, and consequently their utility in LMICs. Reference Hasan, Bhatti and Mohsin4Reference Daenen, Lacour-Gayet and Aberg6 The Hasan et al guidelines Reference Hasan, Bhatti and Mohsin4 conceptualized in a public health framework seek to create an actionable system to integrate PCHD care within existing LMIC health systems. Hasan et al propose a tier-based framework for PCHD care based on the World Bank health facilities classification (levels 1-5), defined by the complexity of care provided. In this system, level 1, 2, and 3 centers handle screening, diagnosis, noninvasive management, and referral. Level 4 centers are regional referral centers and offer a comprehensive pediatric cardiac service including cardiac intensive care, cardiac catheterization (PREDIC3T categories 0-4), Reference Quinn, Yeh and Gauvreau7 and surgery (RACHS categories 1-2). Reference Jenkins, Gauvreau, Newburger, Spray, Moller and Iezzoni8 Level 5 centers additionally, offer adult CHD (ACHD) care, all cardiac procedures, transplants, left ventricular assist devices (LVADs), and extracorporeal membrane oxygenation (ECMO). Level 4 centers require pediatric cardiologists but can be staffed with either pediatric or adult anesthetists and cardiothoracic surgeons. Level 5 centers, however, require credentialed pediatric cardiothoracic surgeons and cardiac anesthetists. Additionally, Level 4 centers should provide cardiology and cardiothoracic surgery training, while level 5 centers should also offer research programs.

The UK report on cardiac services recommends 2 pediatric cardiologists per million population. Reference Hall, More and Camm9 This figure is based on UK demographics and may need to be higher in lower-income settings with higher birth rates and lower median age, resulting in a higher CHD burden. For example, Daenen et al Reference Daenen, Lacour-Gayet and Aberg6 recommend a minimum of 0.4 (0.33-0.5) cardiothoracic surgeons per million population, whereas Sliwa et al Reference Sliwa, Zühlke and Kleinloog10 recommend that African cardiac centers should have 1.25 cardiothoracic surgeons per million population. This recommendation accounts for higher African fertility rates (4.7 in Africa vs 1.6 in Europe) 11 and is proportionally similar.

This landscape analysis of pediatric cardiac services in Africa seeks to quantify gaps in PCHD service delivery relative to these established guidelines. Understanding where and how these services fall short is essential to informing targeted interventions and strategies aimed at aligning African PCHD services with global best practices, ultimately ensuring equitable access to high-quality cardiac care for all children across the continent.

Methods

We conducted a cross-sectional electronic survey to evaluate PCHD services in Africa.

Survey Development and Testing

The survey was developed by the authors belonging to the University of Cape Town’s Children’s Heart Disease Research Unit in collaboration with Pan-African Network for Pediatric and Congenital Hearts, a special interest group of the Pan-African Society of Cardiology, the African Society for Pediatric and Congenital Heart Surgery and the World Society for Pediatric and Congenital Heart Surgery, the International Quality Improvement Collaborative for Congenital Heart Disease, Children’s Heart Link, and Global Alliance for Rheumatic and Congenital Hearts (ARCH).

Following pretesting, the survey was pilot tested with three pediatric cardiologists, one adult cardiologist, and one medical officer for comprehensiveness and clarity. Reference Burns, Duffett and Kho12 The individuals comprising the test group were deliberately selected to align with the expected professional diversity of the survey respondents.

The survey was developed in English only and consisted of 138 possible questions. Branching logic was used to reduce respondent burden by hiding irrelevant questions, and the average completion time was 28 min. The survey included respondent-level, institution-level, and national-level queries. Respondent-level questions included profession, specialization, and practicing institution. Institution-level details included staffing, infrastructure, and services for pediatric cardiology, cardiac catheterization, cardiothoracic surgery, and intensive care, for ACHD, and cardio-obstetrics. The survey also included information related to screening programs, cardiac imaging, electronic health records and databases, fellowship training, and financial organization. National-level questions related to the availability and provision of pediatric cardiology, interventional cardiac catheterization, pediatric cardiothoracic surgery, and fellowship training.

Recruitment and Data Collection

Potential respondents were selected by purposive sampling. A literature review was performed by searching the PubMed/ MEDLINE and Google Scholar databases using a combination of pediatric cardiology, cardiology, cardiothoracic surgery, cardiac surgery, Africa, and country-specific keywords. Local African authors were identified and contacted via included contact details or via follow-up contact tracing. An extensive internet search for PCHD practitioners and institutions was also conducted, with a review of hospital, university websites, and professional social network websites, including LinkedIn and ResearchGate. Additionally, the authors leveraged their individual professional networks to contact potential collaborators, drawing on connections to the World Health Organization and other global entities. Potential respondents were contacted via email in English, French, and Portuguese and sent URL and QR-code links to the online survey. Where necessary, follow-up by telephone was conducted in English only.

The study protocol was reviewed and approved by Human Research Ethics Committee, University of Cape Town (HREC459-2023). No personally identifiable staff or patient data were collected, and consent to participate was obtained in the survey preface. Survey distribution was commenced on June first, 2023. All eligible responses received before December first, 2023, were incorporated into the analysis.

Data Analysis

Data were analyzed using R (version 4.4.0, R Foundation). Reference Ihaka and Gentleman13 The survey permitted multiple respondents per country and institution. These responses were amalgamated to create summaries at both the national and institutional levels. The African countries and regions defined in this study correspond to the 55 member states and five regions recognized by the African Union (AU), as detailed in the AU’s official country profiles. 14

Before combining the data, categorical responses were scrutinized for discrepancies between countries and institutions. If any were discovered, additional questionnaires were distributed for clarification. Likewise, continuous data underwent scrutiny for inconsistencies and outliers.

Institutions were ranked according to a composite score based on Hassan et al’s recommendations for developing PCHD services in LMICs. Reference Hasan, Bhatti and Mohsin4 Variables relating to human resources, PCHD services, infrastructure, training, and health data infrastructure were assessed. Radar plots were utilized to visually compare the percentage of institutions meeting criteria for level 4 or 5 PCHD centers across the five categories within each UN African subregion. Radar plots allow for a multidimensional comparison, revealing the relative strengths and weaknesses across categories and subregions. Each axis of the radar plot represents one category, with values ranging from 0% to 100%, indicating the proportion of institutions meeting the specified criteria. Higher values along an axis indicate greater compliance with the criteria, while lower values signify gaps in service provision. The plotted points are then connected to form polygons for each region, asymmetry indicates discrepancies between the different categories and areas of strength or potential targets for intervention. In addition to examining the primary categories, radar plots were also used to analyze specific subcriteria within three key categories: human resources, infrastructure, and PCHD services.

Results

Respondents

There were 124 respondents, from 96 institutions, in 70 cities, and 45 different countries in Africa representing 93.7% of the African population. The cumulative population of the 10 countries with nonrespondents amounts to only 6.3% of the total African population. 15 These 10 countries were Cape Verde, Central African Republic, Djibouti, Equatorial Guinea, Eritrea, Guinea, Ivory Coast, Madagascar, Republic of the Congo, and the Sahrawi Arab Democratic Republic.

Most respondents were interventional pediatric cardiologists (31%, 38/119), followed by noninterventional pediatric cardiologists (26%), pediatricians (12%), pediatric cardiac surgeons (11%), adult cardiologists (7%), adult cardiac surgeons (4%), and pediatric intensivists (2%). Other respondents (6%) included pediatric cardiology and cardiothoracic surgery fellows, general practitioners, and anesthetists.

National-Level Data

Aggregated country-level data showed that 78% or 35 of the 45 respondent countries had some form of cardiac service (Figure 1). Eighteen countries (40%) were able to provide a full PCHD service including interventional pediatric cardiology and pediatric cardiopulmonary bypass (CPB) cardiac surgery. Ten countries (10/45, 22%) provided pediatric cardiac surgery services but no interventional pediatric cardiology service, of these 4/45 (9%) did not have CPB facilities. Of the 17/45 countries (38%) with no cardiac surgery service, 1 country provided interventional pediatric cardiology services, 6 countries provided a noninterventional cardiology service, and 10 had no PCHD service (Figure 1). Additionally, 49% (22/45) of countries had surgical support from visiting international teams. This included four countries, which rely entirely on visiting teams for surgical interventions, that are not included among the 28 cardiac surgery centers.

Figure 1. Choropleth depicting availability of cardiac services at the national level. Abbreviations: BEN, Benin; BFA, Burkina Faso; CAF, Central African Republic; CIV, Ivory Coast; CMR, Cameroon; COD, Democratic Republic of the Congo; COG, Republic of the Congo; ERI, Eritrea; ESH, Sahrawi Arab Democratic Republic; GAB, Gabon; GHA, Ghana; GIN, Guinea; MAR, Morocco; MWI, Malawi; SEN, Senegal; TUN, Tunisia; UGA, Uganda; ZWE, Zimbabwe.

Pediatric Cardiac Surgery

Aggregated country-level data showed a median number of 1 (interquartile range [IQR]: 0-3.0) pediatric cardiothoracic surgeon per country or 0.04 (IQR: 0.00-0.14) pediatric cardiothoracic surgeons per million population, far below the international recommended ratio of 1 pediatric cardiothoracic surgeon per 800,000 population (1.25 per million population) (Figure 2). Reference Sliwa, Zühlke and Kleinloog10 Of the 44 respondent countries, 20 (45%) had no pediatric cardiothoracic surgeons, 8 (18%) countries had one surgeon, 10 (23%) countries had one to five surgeons, and 6 (14%) had more than five surgeons.

Figure 2. Choropleth depicting the number of pediatric cardiothoracic surgeons per million population at the national level. Abbreviations: BEN, Benin; BFA, Burkina Faso; CAF, Central African Republic; CIV, Ivory Coast; CMR, Cameroon; COD, Democratic Republic of the Congo; COG, Republic of the Congo; ERI, Eritrea; ESH, Sahrawi Arab Democratic Republic; GAB, Gabon; GHA, Ghana; GIN, Guinea; MAR, Morocco; MWI, Malawi; SEN, Senegal; TUN, Tunisia; UGA, Uganda; ZWE, Zimbabwe.

Pediatric Cardiology

Similarly, aggregated country-level data showed a median number of 3 (IQR: 0.17-10) pediatric cardiologists per country or 0.17 (IQR: 0.02-0.35) pediatric cardiologists per million population, below the international recommended ratio of one pediatric cardiologist per 500,000 population (2 per million population) (Figure 3). Reference Hall, More and Camm9 Of the 43 respondent countries, 11 (26%) had no pediatric cardiologists, 5 (12%) countries had one cardiologist, 10 (23%) countries had one to five cardiologists, and 17 (40%) had more than five cardiologists.

Figure 3. Choropleth depicting the number of pediatric cardiologists per million population at the national level. Abbreviations: BEN, Benin; BFA, Burkina Faso; CAF, Central African Republic; CIV, Ivory Coast; CMR, Cameroon; COD, Democratic Republic of the Congo; COG, Republic of the Congo; ERI, Eritrea; ESH, Sahrawi Arab Democratic Republic; GAB, Gabon; GHA, Ghana; GIN, Guinea; MAR, Morocco; MWI, Malawi; SEN, Senegal; TUN, Tunisia; UGA, Uganda; ZWE, Zimbabwe.

Institutions

Our results include respondents from 96 different hospitals across Africa, 27 institutions in Eastern Africa, 21 in Western Africa, 20 in Northern Africa, 20 in Southern Africa, and 8 in Central Africa.

Pediatric cardiac surgery

Pediatric cardiac surgery services were available in 53% (51/96) of institutions; however, only 46 institutions (48%) had cardiac perfusion services, with a median of 2 (IQR: 2-2) CPB machines per hospital. Overall, this equates to a median of 0.04 (IQR: 0.03-0.15) centers offering CPB cardiac surgery per million population (Table 1). Southern Africa has the highest proportion of CPB cardiac surgery centers with 0.175 centers per million population, has a z-score of 1.73, the highest positive deviation from the mean rate for all regions, and is the only region outside the range for low-income countries. Reference Vervoort, Babar and Sabatino16 Central Africa has the lowest rate of CPB cardiac surgery centers with 0.005 centers per million population and the highest negative deviation from the mean rate (z-score: −0.75).

Table 1. The Number of Cardiac Surgery Centers With Cardiopulmonary Bypass Services per Million Population Overall and Stratified by AU Subregion

Abbreviation: AU, African Union; CPB, cardiopulmonary bypass.

a z-score indicates how many standard deviations each region’s rate is from the mean of all the regions.

Most hospitals had two operating rooms (median 2, IQR: 1-2, range 0-5), with most (58.8%, 30/51) of them being used for pediatric cases only. On average, these centers performed a median of 98 (IQR: 33-150) pediatric CHD surgeries and 20 (IQR: 8-50) pediatric acquired heart disease surgeries annually.

Most of the responding cardiac surgery programs were run by cardiothoracic surgeons with formal training in congenital heart surgery (42/51, 82%). The remaining programs were run by cardiothoracic surgeons with no formal training in congenital heart surgery (5/51, 9.8%) and a combination of general surgeons, pediatric surgeons, and sessional staff (4/51, 7.9%). Of these program leads, 29/51 (57%) had greater than 10 years of experience, 15/51 (29%) had 5 to 10 years’ experience and 6/51 (12%) had less than 5 years’ experience. The median number of formally trained cardiothoracic surgeons in full-time employment per hospital was 2 (IQR: 2-4.8), with a median of 1 (IQR: 1-2) surgeons with formal training in congenital heart disease surgery per hospital. Thirty-four hospitals (34/51, 66.7%) had a pediatric cardiac anesthesiologist, with a median of 2 (IQR: 1-4) pediatric cardiac anesthesiologists per hospital. There was a median of 4.5 (IQR: 3-10) operating room nurses per hospital.

Pediatric cardiology

Seventy-five hospitals provided pediatric cardiology services. Forty-four (46%, 44/96) of these performed interventional pediatric cardiac catheterizations, with a median of 37.5 (IQR: 13-100) performed annually. Thirty-one hospitals (32%, 31/96) provided a noninterventional cardiology service. Eighteen hospitals (18/96, 19%) had no PCHD care services.

Most (90.7%, 68/75) pediatric cardiology services were run by a formally trained pediatric cardiologist, five services were run by general pediatricians, one center was run by a combination of adult and pediatric cardiologists, and one center did not specify. Most of these department heads had more than 10 years’ experience (63%, 47/75), 20/75 (27%) had 5 to 10 years’ experience, 7/75 (9%) had less than 5 years’ experience, and 1 did not specify. The median number of doctors in fulltime employment per cardiology service was 4 (IQR: 2-8, max 35); of this median 2 (IQR: 1-4, max 32) were formally trained pediatric cardiologists. Cardiac catheterization laboratories were available for 72% (54/75) of services, of these 89% (48/ 54) were onsite, 69% (37/54) of these had dedicated surgical backup, 15% (8/54) were used exclusively for pediatric cases, and 56% (30/54) had biplane fluoroscopy machines. There was a median of 4 (IQR: 2-7) catheterization laboratory nurses per hospital. Availability of cardiac catheterization equipment was generally low, especially for specialized equipment such as ultra-high-pressure balloons, small covered vascular stents, and ventricular septal defect (VSD) closure devices. Coronary stents (which may be utilized in pediatric cases) and standard balloons were “always available” in most centers. Similarly, patent ductus arteriosus (PDA) and atrial septal defect (ASD) closure devices were also commonly “always available” (Figure 4).

Figure 4. Likert scale depicting availability of cardiac catheterization equipment. Abbreviations: ASD, atrial septal defect; PDA, patent ductus arteriosus; VSD, ventricular septal defect.

Adult CHD and Cardio-Obstetric Services

Pediatric patients were transferred to an adult service at a median of 17 years of age (IQR: 15-18). Dedicated ACHD services were available in 12 centers, in six countries: four centers in Egypt, four centers in South Africa, and one center each in Ethiopia, Guinea-Bissau, Namibia, and Niger. Cardio-obstetric services were available in nine centers in four countries: four centers in South Africa, two centers in Egypt, two centers in Mozambique, and one center in Sudan.

Fellowship Training

More than one-half (25/45, 56%) of the respondent countries reported no pediatric cardiology or cardiothoracic surgery training program. Of the 20 countries with fellowship programs, 13/45 (29%) had both cardiology and cardiothoracic surgery fellowship programs, 5/45 (11%) only had cardiology programs, and 2/45 (4%) only had cardiothoracic surgery fellowship programs (Figure 5). At an institutional level, there were 19 cardiology fellowship programs, most of which trained fellows locally (13/19, 69%), 5/19 (26%) programs trained cardiology fellows both locally and internationally, and 1 program did not specify. Most (18/19, 95%) cardiology programs provided official certification at completion of training, and trained a median of 2 (IQR: 1.5-3, range 1-10) pediatric cardiologists per year. Similarly, there were 19 cardiothoracic surgery fellowship programs which were primarily local (11/19, 58%), with 6/19 (32%) programs training fellows both locally and internationally, 1/19 (5%) program training fellows exclusively internationally, and 1 program not specifying. Most (17/ 19 90%) cardiothoracic surgery programs provided official certification at completion of training. Each institution trained a median of 3.5 (IQR: 2-4.3, range 1-12) pediatric cardiothoracic surgeons annually.

Figure 5. Choropleth depicting the availability of pediatric cardiology and cardiothoracic surgery fellowship programs at the national level. Abbreviations: BEN, Benin; BFA, Burkina Faso; CAF, Central African Republic; CIV, Ivory Coast; CMR, Cameroon; COD, Democratic Republic of the Congo; COG, Republic of the Congo; ERI, Eritrea; ESH, Sahrawi Arab Democratic Republic; GAB, Gabon; GHA, Ghana; GIN, Guinea; MAR, Morocco; MWI, Malawi; SEN, Senegal; TUN, Tunisia; UGA, Uganda; ZWE, Zimbabwe.

Pediatric and Congenital Cardiac Service Levels

The 96 institutions were ranked according to a composite score based on Hasan et al’s recommendations for developing PCHD services in LMICs. Reference Hasan, Bhatti and Mohsin4 Twelve responses, from nine institutions were excluded from this analysis due to missing data. When ranked according to human resources, services, infrastructure, training, and health-data infrastructure, there were no national-level referral centers (Level 5) and only eight regional-level referral centers (Level 4): five from Southern Africa, two from Northern Africa and one from Eastern Africa (Table 2). By category, only 29/87 (33%) of institutions reported having level 4 or 5 human resources, 22/87 (25.3%) of institutions met level 4 or 5 criteria for PCHD services, 28/87 (32.2%) met level 4 or 5 criteria for available infrastructure, 23/87 (26.4%) met level 4 or 5 criteria for PCHD training, and 55/87 (63%) had sufficient health data infrastructure to enable quality control measures to be implemented. Stratification by AU subregion reveals geographic discrepancies. The radar plot in Figure 6 shows the proportion of centers in each region which meet either level 4 or 5 criteria in human resources, services, infrastructure, training, and health data infrastructure. Analysis of the human resources, PCHD services, and infrastructure categories subcriteria, stratified by African Union (AU) subregion (Figure 7) reveal further discrepancies.

Table 2. The Proportion of Respondent Health Centers Meeting All Hasan et al Reference Hasan, Bhatti and Mohsin4 Criteria for Either Level 4 or Level 5 PCHD Centers, Stratified by AU Subregion and Criteria Category

Abbreviations: AU, African Union; PCHD, Pediatric and Congenital Heart Disease.

Figure 6. Radar plot showing the percentage of institutions meeting the category criteria for Level 4 or 5 Pediatric and Congenital Heart Disease (PCHD) centres Reference Hasan, Bhatti and Mohsin4 across African Union (AU) subregions (Northern, Western, Central, Eastern, and Southern Africa). The categories assessed include Human Resources, PCHD Services, Infrastructure, Training, and Health Data Infrastructure. Each axis represents one of these categories, with the plotted points connected to form a polygon for each subregion. The extent of the polygon along each axis indicates the proportion of institutions in that subregion meeting the specific category criteria, with asymmetry indicating imbalance or disparity between the different categories. This allows for a visual comparison of strengths and gaps in PCHD care across the different regions.

Figure 7. Radar plots showing the percentage of institutions meeting level 4 or 5 Pediatric and Congenital Heart Disease (PCHD) Reference Hasan, Bhatti and Mohsin4 subcriteria for categories (A) Human resources, (B) PCHD Services, and (C) Infrastructure. Data are stratified by African Union (AU) subregions (Northern, Western, Central, Eastern, and Southern Africa). Each axis represents one of these subcriteria, with the plotted points connected to form a polygon for each subregion. The extent of the polygon along each axis indicates the proportion of institutions in that subregion meeting the specific subcriteria, allowing for a visual comparison of strengths and gaps across the different regions. Abbreviations: CHD, congenital heart disease; ICU, intensive care unit; PCHD, pediatric and congenital heart disease.

Discussion

The provision of PCHD services in Africa is critically hampered by severe shortages of specialized personnel, inadequate institutional capacity, significant infrastructure deficiencies, and pronounced geographic disparities, with only 18 countries offering comprehensive PCHD services and many lacking essential training programs, resulting in inadequate care for African children with heart disease, high unmet needs, and preventable morbidity and mortality among children with heart disease (Table 3).

Table 3. Summary of Study Findings and List of Recommendations

Abbreviations: APFP, African Pediatric Fellowship Program; LMIC, low- to middle-income country; PCHD, Pediatric and Congenital Heart Disease.

While 78% or 35 of the 45 respondent countries report having some form of cardiac service, only 28 (62%) of the 45 countries surveyed provide pediatric cardiac surgery and 4 of these countries did not have CPB facilities. Additionally, the number of pediatric cardiologists and cardiothoracic surgeons is below international population-based recommendations. Only Libya and Mauritius have the recommended two pediatric cardiologists per million population, and no country has the recommended 1.25 cardiothoracic surgeons per million population.

Less than one-half (46/96, 48%) of respondent institutions provided CPB cardiac surgery, with a median of 0.04 (IQR: 0.03-0.15) centers offering CPB cardiac surgery per million population and with critical deficiencies in Central Africa (Table 1). This ratio is similar to previous estimates for low-income countries of 0 (IQR: 0-0.06) centers per million population and well below that of upper-middle (0.52, IQR: 0-1.02) and high-income (0.75, IQR: 0-1.44) countries. Reference Vervoort, Babar and Sabatino16 When ranked according to a composite score based on the recommendations for LMICs PCHD services by Hasan et al, Reference Hasan, Bhatti and Mohsin4 no institution met all level 5—national-level PCHD referral center criteria and only 8 of 87 (9.2%) respondent institutions met all available criteria for level 4 —regional PCHD referral centers (Table 2).

Stratification by AU subregion highlights geographic disparities in PCHD services, with Central and Western Africa showing the greatest need for development (Figure 6). In Southern Africa (black), there is no specific category that is lacking and a generalized expansion of PCHD resources is warranted. Northern (red) and Eastern Africa (blue) are similar but with a lower proportion of centers meeting level 4 or 5 criteria, particularly for PCHD services in Northern Africa, largely related to gaps in ACHD services (Figure 7C).

In contrast, Western (yellow) and Central Africa (green) show generalized deficiencies, with significant gaps in PCHD services and infrastructure, especially for Central Africa (Figure 6). In Western Africa, this is primarily due to deficiencies in human resources with a disproportionate lack of pediatric cardiologists (Figure 7A), lack of infrastructure for interventional services, especially cardiac catheterization (Figure 7C), and related deficiencies in the provision of catheterization services.

The situation in Central Africa is similar but worse with a critical lack of level 4 or 5 cardiothoracic surgery, anesthesiology, and perfusionist human resources. When combined with the severe lack of surgical infrastructure it is unsurprising that the provision of cardiothoracic surgery services is lacking (Figure 7B). Despite similar proportions of centers with level 4 or 5 cardiology human resources to that seen in Eastern Africa, in Central Africa there are no centers with level 4 or 5 catheterization infrastructure, which severely hampers the provision of interventional catheterization services.

These data are especially concerning given the significant shortage of pediatric cardiology and cardiothoracic surgery fellowship programs. Only 13/45 (29%) countries report having both pediatric cardiology and cardiothoracic surgery fellowship training programs (Figure 5) with the greatest deficits in Western and Central Africa (Figure 7). This shortage must be addressed if PCHD capacity is to be increased. One promising model for addressing this gap is the African Pediatric Fellowship Program (APFP) at the University of Cape Town. Reference Wilmshurst, Morrow, du Preez, Githanga, Kennedy and Zar17 The APFP provides specialized training to doctors from across Africa, including in pediatric cardiology and cardiothoracic surgery. Through its “train the trainer” model, the APFP equips African specialists with the skills needed to return to their home countries and train the next generation of health professionals ensuring sustainable growth in the availability of pediatric services across the continent. It would be highly beneficial for other countries in Africa to develop similar programs, enabling them to build African expertise and reduce reliance on external training, further bolstering the continent’s ability to manage pediatric congenital heart disease.

In conclusion, these results emphasize that PCHD services across Africa remain critically insufficient, with significant disparities between regions. Central and Western Africa are particularly underserved, where a lack of vital training programs is likely exacerbating the issue. As progress is made in other health areas, PCHD has become an important focus in the reduction of childhood deaths and the realization of the United Nations’, 2016, Sustainable Development Goals. Despite this, progress in global cardiac surgery, particularly in Africa and other low- and middle-income regions, remains slow.

Limitations

This study is subject to the limitations and biases inherent in surveys. Despite efforts to include a broad range of professionals and a systematic approach to identifying respondents, the sample may not fully represent the entire spectrum of PCHD care providers across Africa, and certain groups may be misrepresented due to the way participants were selected or volunteered to participate. The survey relies on self-reported data from respondents, which is subject to response and recall bias. When ranking institutions according to the Hasan et al guideline, not all criteria used in the guideline were available. As such, the analysis represents a best-case scenario given the available data. For instance, the guideline specifies the equipment and supplies required at each institutional level. Since these data are unavailable, a center that meets level 4 criteria in all categories except equipment and supplies would still be categorized as a level 4 center in this analysis. The same applies to specific unavailable variables within the categories described above. For example, the guideline states that level 4 and 5 centers should provide an electrophysiology service. As these data were not recorded, no center would be downgraded due to a lack of electrophysiology services.

Supplementary material

The supplementary material for this article can be found at https://doi.org/10.1017/S1047951125100504

Acknowledgments

Liesl Zühlke is funded by the South African Medical Research Council (SAMRC) through its Division of Research Capacity Development under the Mid-Career Scientist Program from funding received from the South African National Treasury. The content and findings reported/illustrated are the sole deduction, view, and responsibility of the researcher and do not reflect the official position and sentiments of the SAMRC. Liesl Zühlke also receives support from the National Research Foundation of South Africa (NRFSA), as well as the UK Medical Research Council (MRC) and the Foreign Commonwealth and Development Office (FCDO) under the MRC/FCDO Concordat agreement, via the African Research Leader Award (MR/S005242/1).

Declaration of Conflicting Interests

The author(s) declared no potential conflicts of interest with respect to the research, authorship, and/or publication of this article.

Funding

The author(s) disclosed receipt of the following financial support for the research, authorship, and/or publication of this article: This work was supported by the Division of Research Capacity Development, Foreign Commonwealth and Development Office, UK, National Research Foundation of South Africa, Medical Research Council, (grant number Mid-Career Scientist Program, MR/S005242/1).

Footnotes

*

Respondent countries: Algeria, Angola, Benin, Botswana, Burkina Faso, Burundi, Cameroon, Chad, Comoros, Democratic Republic of the Congo, Egypt, Eswatini, Ethiopia, Gabon, Gambia, Ghana, Kenya, Libya, Malawi, Mali, Mauritania, Mauritius, Morocco, Mozambique, Namibia, Niger, Nigeria, Rwanda, São Tomé and Príncipe, Senegal, Seychelles, Sierra Leone, Somalia, South Africa, South Sudan, Sudan, Tanzania, Togo, Uganda, Zambia, Zimbabwe.

Joint publication statement: This paper has been copublished in World Journal for Pediatric and Congenital Heart Surgery by Sage Publications and Cardiology in the Young by Cambridge University Press.

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Figure 0

Figure 1. Choropleth depicting availability of cardiac services at the national level. Abbreviations: BEN, Benin; BFA, Burkina Faso; CAF, Central African Republic; CIV, Ivory Coast; CMR, Cameroon; COD, Democratic Republic of the Congo; COG, Republic of the Congo; ERI, Eritrea; ESH, Sahrawi Arab Democratic Republic; GAB, Gabon; GHA, Ghana; GIN, Guinea; MAR, Morocco; MWI, Malawi; SEN, Senegal; TUN, Tunisia; UGA, Uganda; ZWE, Zimbabwe.

Figure 1

Figure 2. Choropleth depicting the number of pediatric cardiothoracic surgeons per million population at the national level. Abbreviations: BEN, Benin; BFA, Burkina Faso; CAF, Central African Republic; CIV, Ivory Coast; CMR, Cameroon; COD, Democratic Republic of the Congo; COG, Republic of the Congo; ERI, Eritrea; ESH, Sahrawi Arab Democratic Republic; GAB, Gabon; GHA, Ghana; GIN, Guinea; MAR, Morocco; MWI, Malawi; SEN, Senegal; TUN, Tunisia; UGA, Uganda; ZWE, Zimbabwe.

Figure 2

Figure 3. Choropleth depicting the number of pediatric cardiologists per million population at the national level. Abbreviations: BEN, Benin; BFA, Burkina Faso; CAF, Central African Republic; CIV, Ivory Coast; CMR, Cameroon; COD, Democratic Republic of the Congo; COG, Republic of the Congo; ERI, Eritrea; ESH, Sahrawi Arab Democratic Republic; GAB, Gabon; GHA, Ghana; GIN, Guinea; MAR, Morocco; MWI, Malawi; SEN, Senegal; TUN, Tunisia; UGA, Uganda; ZWE, Zimbabwe.

Figure 3

Table 1. The Number of Cardiac Surgery Centers With Cardiopulmonary Bypass Services per Million Population Overall and Stratified by AU Subregion

Figure 4

Figure 4. Likert scale depicting availability of cardiac catheterization equipment. Abbreviations: ASD, atrial septal defect; PDA, patent ductus arteriosus; VSD, ventricular septal defect.

Figure 5

Figure 5. Choropleth depicting the availability of pediatric cardiology and cardiothoracic surgery fellowship programs at the national level. Abbreviations: BEN, Benin; BFA, Burkina Faso; CAF, Central African Republic; CIV, Ivory Coast; CMR, Cameroon; COD, Democratic Republic of the Congo; COG, Republic of the Congo; ERI, Eritrea; ESH, Sahrawi Arab Democratic Republic; GAB, Gabon; GHA, Ghana; GIN, Guinea; MAR, Morocco; MWI, Malawi; SEN, Senegal; TUN, Tunisia; UGA, Uganda; ZWE, Zimbabwe.

Figure 6

Table 2. The Proportion of Respondent Health Centers Meeting All Hasan et al4 Criteria for Either Level 4 or Level 5 PCHD Centers, Stratified by AU Subregion and Criteria Category

Figure 7

Figure 6. Radar plot showing the percentage of institutions meeting the category criteria for Level 4 or 5 Pediatric and Congenital Heart Disease (PCHD) centres4 across African Union (AU) subregions (Northern, Western, Central, Eastern, and Southern Africa). The categories assessed include Human Resources, PCHD Services, Infrastructure, Training, and Health Data Infrastructure. Each axis represents one of these categories, with the plotted points connected to form a polygon for each subregion. The extent of the polygon along each axis indicates the proportion of institutions in that subregion meeting the specific category criteria, with asymmetry indicating imbalance or disparity between the different categories. This allows for a visual comparison of strengths and gaps in PCHD care across the different regions.

Figure 8

Figure 7. Radar plots showing the percentage of institutions meeting level 4 or 5 Pediatric and Congenital Heart Disease (PCHD)4 subcriteria for categories (A) Human resources, (B) PCHD Services, and (C) Infrastructure. Data are stratified by African Union (AU) subregions (Northern, Western, Central, Eastern, and Southern Africa). Each axis represents one of these subcriteria, with the plotted points connected to form a polygon for each subregion. The extent of the polygon along each axis indicates the proportion of institutions in that subregion meeting the specific subcriteria, allowing for a visual comparison of strengths and gaps across the different regions. Abbreviations: CHD, congenital heart disease; ICU, intensive care unit; PCHD, pediatric and congenital heart disease.

Figure 9

Table 3. Summary of Study Findings and List of Recommendations

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