Academic Editor: Junfei Gu

Received: 24 February 2025

Revised: 12 March 2025

Accepted: 17 March 2025

Published: 21 March 2025

Citation: El Bilali, H.; Nanema, R.K.;

Rokka, V.-M.; Dan Guimbo, I.; Kiebre,

Z.; Siciliano, R.A.; Tietiambou, S.R.F.;

Dambo, L.; Nanema, J.; Grazioli, F.;

et al. Research on Sweet Potato

(Ipomoea batatas) in West Africa: State,

Features and Gaps. Agronomy 2025, 15,

766. https://doi.org/10.3390/

agronomy15040766

Copyright: © 2025 by the authors.

Licensee MDPI, Basel, Switzerland.

This article is an open access article

distributed under the terms and

conditions of the Creative Commons

Attribution (CC BY) license

(https://creativecommons.org/

licenses/by/4.0/).

Review

Research on Sweet Potato (Ipomoea batatas) in West Africa:
State, Features and Gaps
Hamid El Bilali 1,* , Romaric Kiswendsida Nanema 2 , Veli-Matti Rokka 3 , Iro Dan Guimbo 4, Zakaria Kiebre 2 ,
Rosa Anna Siciliano 5 , Sheirita Reine Fanta Tietiambou 6 , Lawali Dambo 7, Jacques Nanema 8,
Francesca Grazioli 9 and Filippo Acasto 10

1 International Centre for Advanced Mediterranean Agronomic Studies, Mediterranean Agronomic Institute of
Bari (CIHEAM-Bari), Via Ceglie 9, 70010 Valenzano, Italy

2 Department of Plant Biology and Physiology, Joseph Ki-Zerbo University, 03 BP, Ouagadougou 7021,
Burkina Faso; romaric.nanema@ujkz.bf (R.K.N.); zakaria.kiebre@ujkz.bf (Z.K.)

3 Natural Resources Institute Finland (Luke), Myllytie 1, 31600 Jokioinen, Finland; veli-matti.rokka@luke.fi
4 Department of Rural Engineering, Water and Forests, Faculty of Agronomy, Abdou Moumouni University,

P.O. Box 237, Niamey BP 10662, Niger; danguimbo@yahoo.fr
5 Institute of Food Sciences, National Research Council of Italy (CNR), Via Roma 64, 83100 Avellino, Italy;

rosa.siciliano@isa.cnr.it
6 University Centre of Gaoua, Nazi BONI University, 01 BP, Bobo-Dioulasso 1091, Burkina Faso;

tietiambou.fanta@gmail.com
7 Department of Geography, Faculty of Letters and Human Sciences, Abdou Moumouni University,

P.O. Box 237, Niamey BP 10662, Niger; lawali.dambo@gmail.com
8 Programme Agrinovia, Joseph Ki-Zerbo University, 03 BP, Ouagadougou 7021, Burkina Faso;

jacquesnanema@yahoo.fr
9 Alliance Bioversity International—CIAT (Centro Internacional de Agricultura Tropical), Via San Domenico 1,

00153 Rome, Italy; f.grazioli@cgiar.org
10 Italian Agency for Development Cooperation (AICS), Ouaga 2000—Secteur 54, Arrondissement N. 12,

Ouagadougou 01, Burkina Faso; filippo.acasto@aics.gov.it
* Correspondence: elbilali@iamb.it

Abstract: Although sweet potato (Ipomoea batatas) is gaining importance in West Africa, it
remains uncertain whether the research is adequately advanced to support the promotion
of this crop in the region. Consequently, this systematic review of 125 articles provides
a detailed overview of studies focused on sweet potatoes in West Africa. The paper
explores various bibliometrics, the research geographic spread, and the topics discussed
(e.g., food security and nutrition, climate resilience, livelihoods). The study indicates that
sweet potato has the potential to address multiple issues in West Africa, including food
and nutrition insecurity (especially micronutrient deficiencies, e.g., vitamin A) as well as
poverty. However, it also reveals significant research gaps in terms of geographical and
thematic areas. From a geographical perspective, research is primarily conducted in Nigeria
and Ghana. From a thematic perspective, there are deficiencies in areas like economics
and social sciences, applications in animal husbandry, marketing, use of leaves, irrigation
methods, and impacts on climate resilience and livelihoods. There is a pressing need for
collaborative research and knowledge exchange among nations to fully realize the potential
of sweet potato and develop its value chains to contribute to sustainable socio-economic
development across West Africa.

Keywords: neglected and underutilized species; NUS; orphan crop; I. batatas; sweetpotato;
Sahel; tuber; climate change; food security; SUSTLIVES

Agronomy 2025, 15, 766 https://doi.org/10.3390/agronomy15040766

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Agronomy 2025, 15, 766 2 of 32

1. Introduction
Sweet potato (Ipomoea batatas), also known as sweetpotato, is a dicotyledonous plant

that is part of the Convolvulaceae family [1]. Among the roughly 1000 species in the
Convolvulaceae family, I. batatas stands out as the only significantly important crop. The
genus Ipomoea, which includes the sweet potato, also features various garden flowers
commonly referred to as morning glories. Some organizations and researchers recommend
writing the name as one word—sweetpotato—to highlight its genetic distinction from both
common potatoes and yams (Dioscorea), thereby reducing confusion about its classification
as a type of common potato [2,3]. Currently, the two-word format is predominantly used [4].
The large, sweet-tasting tuberous roots of the sweet potato serve as a root vegetable [5,6].
Though they share the same order, Solanales, I. batatas is only vaguely related to Solanum
tuberosum, the common potato. However, though sweet potato and common potato are not
closely related botanically, they do have a common linguistic origin [7].

The sweet potato originates from the tropical areas of the Americas [8,9]. Sweet
potatoes became a popular food crop in the Pacific Ocean islands [10], South India, Uganda,
and various other African nations [11]. Nowadays, they are grown in temperate areas
where there is enough water [12]. The plant cannot withstand frost. It thrives best at a
usual temperature of 24 ◦C, requiring ample sunlight. An annual rainfall of 750–1000 mm
is deemed ideal. Sweet potatoes are vulnerable to drought during the tuber formation
phase and are not resilient to waterlogged conditions [13]. Tubers are typically cured after
harvest to enhance their storage life, flavour, and nutritional value, as well as to allow the
healing of skin wounds [14,15].

The plant is a perennial vine that is herbaceous. The edible tuberous root is elongated
and tapering, characterized by a smooth skin that comes in various colours, including
beige, brown, orange, purple, red, and yellow. The flesh colour can vary from beige to
orange, pink, purple, red, violet, white, and yellow. Cultivars of sweet potatoes that have
clear-coloured flesh (e.g., white, pale-yellow) tend to be less sweet and moist compared to
those with dark-coloured flesh (e.g., red, pink, orange) [3]. The time it takes for tuberous
roots to mature varies between two to nine months based on the cultivar and environmental
conditions. Short-cycle varieties can be cultivated as seasonal summer crops in temperate
regions. Sweet potatoes are primarily propagated through cuttings from stems or roots,
or by adventitious shoots (i.e., “slips”) emerging from tubers during their storage period.
Generally, sweet potato seeds are utilized solely for breeding purposes [16].

The crop is relatively simple to plant since it is propagated using vine cuttings instead
of seeds. It thrives in various agricultural environments and faces minimal natural threats,
so the use of pesticides is required infrequently. Sweet potato is affected by relatively
few pests and diseases. It is affected by the sweet potato chlorotic stunt virus (SPCSV)
and sweet potato feathery mottle virus [17,18]. Sweet potato is also impacted by several
species of Phytophthora, including P. carotovorum, P. odoriferum, and P. wasabiae [19]. It can
be cultivated in different types of soil but prefers well-drained, light-to-medium-textured
soils [5]. Although sweet potatoes can flourish in poor soil with minimal fertilization [20,21],
they are highly susceptible to aluminum toxicity [5]. Additionally, because the swiftly
growing vines overshadow weeds, there is minimal need for weeding.

In 2020, the worldwide production of sweet potatoes reached approximately 89 million
tons, with China accounting for 55% of the total global production. The next largest
producers were Malawi, Tanzania, and Nigeria [22]. In 2022, the list of the top 20 world
countries in terms of production was still topped by China with more than 46 million
tons [22]. However, the top 20 list featured many African countries such as Malawi,
Tanzania, Nigeria, Angola, Rwanda, Uganda, Madagascar, Ethiopia, Burundi, Kenya, the



Agronomy 2025, 15, 766 3 of 32

Democratic Republic of the Congo (DRC), and Cameroon. Meanwhile, the average yield
ranged from just 1752.3 kg/ha in Chad to 44,317.9 kg/ha in Congo (Table A1).

According to FAO [23], sweet potato is among the most productive crops in terms of
land use, generating around 70,000 kcal per hectare per day. The sweet potato’s tuberous
roots are the most significant product. In certain tropical regions, these tubers serve as a
primary food source. Cooking the tubers before eating enhances their nutritional value and
digestibility, even though they can be consumed raw [24]. Cooked sweet potato (baked
with skin) is rich in water and carbohydrates and has low protein and minimal fat contents.
Sweet potatoes offer lower edible energy and protein per weight compared to cereals like
rice, wheat, and maize; however, they are more nutrient-dense than these grains [25]. Sweet
potatoes are an excellent source of vitamins like A, C, and B6. They also serve as a moderate
source of potassium. Sweet potato varieties that feature dark-coloured flesh have higher
contents of beta-carotene, converted into vitamin A during digestion, compared to those
with lighter-coloured flesh. The cultivation of sweet potato is being promoted in Africa
due to the significant issue of vitamin A deficiency. Sun-dried sweet potato tubers serve
as a fundamental food for individuals in Uganda [26]. Sweet potato is a popular crop and
food in different countries across the globe, such as Papua New Guinea [27], Kenya [28],
Egypt [29], Ethiopia [30], the United States [31–34], and Italy [35].

Furthermore, its leaves are consumable and can be cooked similarly to spinach [36].
The young leaves are commonly eaten as a vegetable in countries of West Africa
(e.g., Guinea, Liberia, Sierra Leone), in addition to being popular in Uganda, East Africa [26].
As reported by the FAO [37], leaves and shoots provide rich sources of vitamins (e.g., A, C,
B2). Mature leaves can be utilized as feed for livestock [26].

Sweet potato also has some industrial applications. In Southern America, the liquid
extracted from red sweet potato tubers was traditionally mixed with lime juice to create a
dye; adjusting the juice ratios allows for the achievement of various shades ranging from
pink to black [38]. Additionally, the colour derived from purple sweet potatoes is utilized
as a natural food colouring [39]. Sweet potato has been processed in several formulations
and products with a variety of ingredients [40,41].

Despite its huge potential, sweet potato is often regarded as an underutilized crop.
While various African nations are involved in its production, it remains unclear whether
the research is sufficiently advanced to support the crop’s promotion, especially in West
Africa. Previous reviews on sweet potatoes have either become outdated or only partially
addressed the topic from geographical and thematic perspectives (Table A2). Additionally,
no comprehensive bibliometric or content analysis has been conducted for all of West Africa.
This indicates a substantial gap in the research, as there has not been a recent systematic
review focusing on sweet potatoes in the region. Therefore, this systematic review aims to
provide an in-depth summary of research concerning sweet potatoes in West Africa. The
article includes bibliometric metrics and examines the geographic spread of the studies. It
also highlights the topics discussed in the academic literature related to sweet potatoes in
West Africa, specifically regarding their potential role in sustainable development in terms
of food and nutrition security, climate resilience, and livelihood.

2. Methods
This article covers the West Africa region (Figure 1). The systematic review [42,43]

is based on a search conducted on the Web of Science Core Collection on 31 May 2024.
The search utilized the subsequent query: (“Ipomoea batatas” OR “I. batatas” OR “sweet
potato” OR sweetpotato OR batata) AND (Togo OR Senegal OR Sahel OR Nigeria OR Niger OR
Mauritania OR Mali OR Liberia OR Guinea OR Ghana OR Gambia OR Burkina OR Benin OR

“West* Africa” OR “Sierra Leone” OR “Ivory Coast” OR “Guinea-Bissau” OR “Côte d’Ivoire” OR



Agronomy 2025, 15, 766 4 of 32

“Cote d’Ivoire” OR “Cape Verde” OR “Cabo Verde”). The search yielded 368 items. The process
of selecting suitable publications was guided by the approach used by El Bilali et al. [44,45].

Agronomy 2025, 15, x FOR PEER REVIEW 4 of 35 
 

 

“West* Africa” OR “Sierra Leone” OR “Ivory Coast” OR “Guinea-Bissau” OR “Côte d’Ivoire” 
OR “Cote d’Ivoire” OR “Cape Verde” OR “Cabo Verde”). The search yielded 368 items. The 
process of selecting suitable publications was guided by the approach used by El Bilali et 
al. [44,45]. 

 

Figure 1. West Africa region. Source: University of Minnesota Libraries Publishing [46]. Stars refer 
to the main, capital cities.  

Figure 2 details the various steps involved in the selection process. In particular, three 
specific criteria were considered for eligibility: geographical relevance (i.e., the 
publication relates to West Africa or a West African nation), thematic relevance (i.e., the 
publication focuses on sweet potato), and document type (i.e., only original research 
papers, chapters, or conference papers were accepted, while editorials and reviews were 
eliminated). After reviewing the titles, 81 publications were removed because they did not 
concern West African nations. In particular, many documents refer to Papua New Guinea 
as well as Australia, Cameroon, Kenya, Malawi, and Uganda. Furthermore, 140 
documents were discarded after examining their abstracts, as they failed to satisfy at least 
one of the inclusion criteria: 27 documents did not discuss sweet potato, 102 did not relate 
to West Africa or West African nations, and 11 lacked abstracts. Concerning geographical 
relevance, the term “Niger” is used in a few articles in reference to Aspergillus niger. 
Further articles refer to Papua New Guinea. Regarding the species, some articles mention 
taro, yam, cassava, and Frafra potato. Finally, 22 documents were removed following a 
comprehensive examination of their full texts, counting 9 reviews. 

The analysis systematically reviewed a total of 125 documents (Table A3). This 
included 107 articles from journals and 18 papers from conferences. The analysis combines 
bibliometric and topical/content analyses (Figure 3). The evaluation of the selected 
documents commenced with an analysis of bibliographic metrics and the geographical 
distribution of studies in West Africa. Next, the identified articles were scrutinized for 
various topics, such as agriculture subsectors, food chain phases, and the role of sweet 
potatoes in promoting food security and good nutrition, supporting livelihoods, and 

Figure 1. West Africa region. Source: University of Minnesota Libraries Publishing [46]. Stars refer to
the main, capital cities.

Figure 2 details the various steps involved in the selection process. In particular, three
specific criteria were considered for eligibility: geographical relevance (i.e., the publication
relates to West Africa or a West African nation), thematic relevance (i.e., the publication
focuses on sweet potato), and document type (i.e., only original research papers, chapters,
or conference papers were accepted, while editorials and reviews were eliminated). After
reviewing the titles, 81 publications were removed because they did not concern West
African nations. In particular, many documents refer to Papua New Guinea as well as
Australia, Cameroon, Kenya, Malawi, and Uganda. Furthermore, 140 documents were
discarded after examining their abstracts, as they failed to satisfy at least one of the inclusion
criteria: 27 documents did not discuss sweet potato, 102 did not relate to West Africa or
West African nations, and 11 lacked abstracts. Concerning geographical relevance, the term
“Niger” is used in a few articles in reference to Aspergillus niger. Further articles refer to
Papua New Guinea. Regarding the species, some articles mention taro, yam, cassava, and
Frafra potato. Finally, 22 documents were removed following a comprehensive examination
of their full texts, counting 9 reviews.

The analysis systematically reviewed a total of 125 documents (Table A3). This in-
cluded 107 articles from journals and 18 papers from conferences. The analysis combines
bibliometric and topical/content analyses (Figure 3). The evaluation of the selected docu-
ments commenced with an analysis of bibliographic metrics and the geographical distri-
bution of studies in West Africa. Next, the identified articles were scrutinized for various
topics, such as agriculture subsectors, food chain phases, and the role of sweet potatoes in
promoting food security and good nutrition, supporting livelihoods, and enhancing cli-
matic and ecosystemic resilience. All analyses followed the approach utilized for mapping
research on moringa [45], roselle [47] and Bambara groundnut [44].



Agronomy 2025, 15, 766 5 of 32

Agronomy 2025, 15, x FOR PEER REVIEW 5 of 35 
 

 

enhancing climatic and ecosystemic resilience. All analyses followed the approach 
utilized for mapping research on moringa [45], roselle [47] and Bambara groundnut [44]. 

 

Figure 2. Selection of the appropriate articles to be incorporated into the review regarding sweet 
potatoes in West Africa. 

 

Figure 3. Organization of the review. 

Figure 2. Selection of the appropriate articles to be incorporated into the review regarding sweet
potatoes in West Africa.

Agronomy 2025, 15, x FOR PEER REVIEW 5 of 35 
 

 

enhancing climatic and ecosystemic resilience. All analyses followed the approach 
utilized for mapping research on moringa [45], roselle [47] and Bambara groundnut [44]. 

 

Figure 2. Selection of the appropriate articles to be incorporated into the review regarding sweet 
potatoes in West Africa. 

 

Figure 3. Organization of the review. Figure 3. Organization of the review.



Agronomy 2025, 15, 766 6 of 32

3. Results and Discussion
3.1. Bibliometrics of Research on Sweet Potato in West Africa

West Africa appears to have a marginal role in the scholarly literature regarding sweet
potatoes, both in Africa and worldwide. A search performed on 31 May 2024 in WoS,
without geographical filters [viz. “Ipomoea batatas” OR “I. batatas” OR “sweet potato” OR
sweetpotato OR batata], yielded 11,318 records. Meanwhile, a similar search considering
the whole African continent [viz. (“Ipomoea batatas” OR “I. batatas” OR “sweet potato” OR
sweetpotato or batata) AND (Africa OR Algeria OR Angola OR Benin OR Botswana OR “Burkina
Faso” OR Burundi OR “Cabo Verde” OR “Cape Verde” OR Ethiopia OR Eswatini OR Eritrea
OR Djibouti OR Egypt OR Congo OR Comoros OR Chad OR Cameroon OR “Ivory Coast”
OR “Equatorial Guinea” OR “Democratic Republic of the Congo” OR “Côte d’Ivoire” OR “Cote
d’Ivoire” OR “Central African Republic” OR Zimbabwe OR Zambia OR Uganda OR Tunisia OR
Togo OR Tanzania OR Swaziland OR Sudan OR Senegal OR Seychelles OR Rwanda OR Nigeria
OR Niger OR Namibia OR Mozambique OR Morocco OR Mauritius OR Mauritania OR Mali OR
Malawi OR Madagascar OR Libya OR Liberia OR Lesotho OR Guinea OR Kenya OR Ghana OR
Gambia OR Gabon OR “South Sudan” OR “South Africa” OR “Sierra Leone” OR Somalia OR
“São Tomé and Príncipe” OR “Guinea-Bissau”)] returned 1124 documents. In comparison to
the 368 records found in the search related to sweet potatoes in West Africa, this suggests
that West Africa represents only about 3.25% of the global literature potentially dealing
with sweet potato. West Africa’s share of in the literature potentially dealing with sweet
potatoes increased to 32.74% when focusing on Africa.

The first research article on sweet potatoes in West Africa indexed in WoS dates to
1991 [48]. Since then, the annual output of publications on sweet potatoes in Africa shows
that interest has been variable and fluctuating. Between 1991 and 2024, the yearly article
numbers shifted dramatically, ranging from zero in certain years (e.g., 1996, 1999, 2002,
2005, 2011) to just one in several others (e.g., 1991, 1994, 1995, 1997, 2003, 2004, 2006, 2013,
2014), with a peak of 12 publications in 2019, 2020, 2021 and 2022. In 2023, 9 papers dealing
with sweet potatoes in West Africa were published, indicating a possible reduction in
interest (compared to 12 publications in 2022).

The compilation of sources and journals (Figure 4) is topped by Acta Horticulturae (8 ar-
ticles, 6.40%), followed by the proceedings of the 9th Triennial African Potato Association
Conference held on 30 June–4 July 2013, in Naivasha, Kenya (8 articles, 6.40%), and Tropical
Agriculture (5 articles, 4.00%). Nevertheless, the 125 selected publications were distributed
across 87 distinct sources and journals, suggesting that research on sweet potatoes in West
Africa lacks a dedicated publication venue.

Most of the publications that meet the eligibility criteria fall within the research areas
of Agriculture (62 publications, 49.60%), Plant Sciences (22 publications, 17.60%), and
Food Science Technology (22 publications, 17.60%) (Figure 5). However, it is important to
highlight that the chosen publications span over 28 research fields (comprising behavioural
sciences, business economics, chemistry, computer science, development studies, ecology,
engineering, entomology, forestry, geology, geography, meteorology, microbiology, nutri-
tion dietetics, pediatrics), reflecting a multidisciplinary landscape of research. Nonetheless,
it can be inferred that the primary focus of this research area is on biological sciences
(e.g., agriculture, plant sciences, food science), with a restricted presence of economics and
social sciences.



Agronomy 2025, 15, 766 7 of 32Agronomy 2025, 15, x FOR PEER REVIEW 8 of 35 
 

 

 

Figure 4. Studies on sweet potato in West Africa–top ten journals and sources. 

Most of the publications that meet the eligibility criteria fall within the research areas 
of Agriculture (62 publications, 49.60%), Plant Sciences (22 publications, 17.60%), and 
Food Science Technology (22 publications, 17.60%) (Figure 5). However, it is important to 
highlight that the chosen publications span over 28 research fields (comprising 
behavioural sciences, business economics, chemistry, computer science, development 
studies, ecology, engineering, entomology, forestry, geology, geography, meteorology, 
microbiology, nutrition dietetics, pediatrics), reflecting a multidisciplinary landscape of 
research. Nonetheless, it can be inferred that the primary focus of this research area is on 
biological sciences (e.g., agriculture, plant sciences, food science), with a restricted 
presence of economics and social sciences. 

 

Figure 5. Studies on sweet potato in West Africa—top ten research areas. 

Figure 4. Studies on sweet potato in West Africa–top ten journals and sources.

Agronomy 2025, 15, x FOR PEER REVIEW 8 of 35 
 

 

 

Figure 4. Studies on sweet potato in West Africa–top ten journals and sources. 

Most of the publications that meet the eligibility criteria fall within the research areas 
of Agriculture (62 publications, 49.60%), Plant Sciences (22 publications, 17.60%), and 
Food Science Technology (22 publications, 17.60%) (Figure 5). However, it is important to 
highlight that the chosen publications span over 28 research fields (comprising 
behavioural sciences, business economics, chemistry, computer science, development 
studies, ecology, engineering, entomology, forestry, geology, geography, meteorology, 
microbiology, nutrition dietetics, pediatrics), reflecting a multidisciplinary landscape of 
research. Nonetheless, it can be inferred that the primary focus of this research area is on 
biological sciences (e.g., agriculture, plant sciences, food science), with a restricted 
presence of economics and social sciences. 

 

Figure 5. Studies on sweet potato in West Africa—top ten research areas. Figure 5. Studies on sweet potato in West Africa—top ten research areas.

The extensive variety of sectors and fields addressed by the studies on sweet potatoes
is clear in the SDGs they relate to (Figure 6). The articles examined in this review regarding
sweet potatoes are linked to 11 SDGs, with the most prominent being 02 (67 documents,
53.60%), 03 (56 documents, 44.80%), 13 (45 documents, 36.00%), and 15 (34 documents,
27.20%). Other SDGs that are less significant include 12 (10 documents), 14 (8 documents),
06 (6 documents), 01 (5 documents), 07 and 11 (2 documents, each), and 09 (1 document).



Agronomy 2025, 15, 766 8 of 32

Agronomy 2025, 15, x FOR PEER REVIEW 9 of 35 
 

 

The extensive variety of sectors and fields addressed by the studies on sweet potatoes 
is clear in the SDGs they relate to (Figure 6). The articles examined in this review regarding 
sweet potatoes are linked to 11 SDGs, with the most prominent being 02 (67 documents, 
53.60%), 03 (56 documents, 44.80%), 13 (45 documents, 36.00%), and 15 (34 documents, 
27.20%). Other SDGs that are less significant include 12 (10 documents), 14 (8 documents), 
06 (6 documents), 01 (5 documents), 07 and 11 (2 documents, each), and 09 (1 document). 

 

Figure 6. Studies on sweet potato in West Africa—main SDGs related with the considered studies. 

The analysis of bibliometric data regarding sweet potato research in West Africa 
indicates that the most notable and productive authors in this field are Edward E. Carey 
(Ghana), Putri Ernawati Abidin (Ghana), and Eric K. Dery (Ghana) (Figure 7). However, 
there is a lack of consistency within the field, as many authors have published only a 
limited number of articles. In fact, among the 506 scholars and researchers who 
contributed to the 125 selected publications, a significant 489 scholars (i.e., 96.64%) 
published two or fewer articles on sweet potatoes. This indicates that even those authors 
who concentrate on sweet potatoes do so sporadically instead of regularly, likely because 
of the lack of structured research initiatives, programmes, and projects focused on sweet 
potatoes in West Africa. 

Figure 6. Studies on sweet potato in West Africa—main SDGs related with the considered studies.

The analysis of bibliometric data regarding sweet potato research in West Africa
indicates that the most notable and productive authors in this field are Edward E. Carey
(Ghana), Putri Ernawati Abidin (Ghana), and Eric K. Dery (Ghana) (Figure 7). However,
there is a lack of consistency within the field, as many authors have published only a limited
number of articles. In fact, among the 506 scholars and researchers who contributed to the
125 selected publications, a significant 489 scholars (i.e., 96.64%) published two or fewer
articles on sweet potatoes. This indicates that even those authors who concentrate on sweet
potatoes do so sporadically instead of regularly, likely because of the lack of structured
research initiatives, programmes, and projects focused on sweet potatoes in West Africa.

Agronomy 2025, 15, x FOR PEER REVIEW 10 of 35 
 

 

 

Figure 7. Research on sweet potato in West Africa—top ten authors and scholars. 

The 125 selected articles on sweet potato were written by researchers connected to 
174 institutions and research centres. Leading the list of affiliated institutions (Figure 8) are 
international organizations like CGIAR (25 articles) and CIP (19 articles). Notable West 
African institutions are primarily located in Nigeria (National Root Crops Research 
Institute, University of Ibadan, Michael Okpara University of Agriculture, Rufus Giwa 
Polytechnic, Adekunle Ajasin University, Landmark University, University of Benin) and 
Ghana (Council of Scientific & Industrial Research, University of Ghana, University of 
Cape Coast, University for Development Studies, Kwame Nkrumah University of Science 
and Technology), and to a lesser extent in the Ivory Coast (Universite Felix Houphouet 
Boigny) and Benin (University of Parakou). Additionally, organizations engaged in sweet 
potato research in West Africa were found outside the region, including in France 
(CIRAD) and Sweden (Swedish University of Agricultural Sciences). 

 

Figure 8. Studies on sweet potato in West Africa—top ten affiliations. CSIR: The Council of Scientific 
and Industrial Research; CGIAR: Consultative Group for International Agricultural Research. 

Figure 7. Research on sweet potato in West Africa—top ten authors and scholars.



Agronomy 2025, 15, 766 9 of 32

The 125 selected articles on sweet potato were written by researchers connected to
174 institutions and research centres. Leading the list of affiliated institutions (Figure 8)
are international organizations like CGIAR (25 articles) and CIP (19 articles). Notable
West African institutions are primarily located in Nigeria (National Root Crops Research
Institute, University of Ibadan, Michael Okpara University of Agriculture, Rufus Giwa
Polytechnic, Adekunle Ajasin University, Landmark University, University of Benin) and
Ghana (Council of Scientific & Industrial Research, University of Ghana, University of
Cape Coast, University for Development Studies, Kwame Nkrumah University of Science
and Technology), and to a lesser extent in the Ivory Coast (Universite Felix Houphouet
Boigny) and Benin (University of Parakou). Additionally, organizations engaged in sweet
potato research in West Africa were found outside the region, including in France (CIRAD)
and Sweden (Swedish University of Agricultural Sciences).

Agronomy 2025, 15, x FOR PEER REVIEW 10 of 35 
 

 

 

Figure 7. Research on sweet potato in West Africa—top ten authors and scholars. 

The 125 selected articles on sweet potato were written by researchers connected to 
174 institutions and research centres. Leading the list of affiliated institutions (Figure 8) are 
international organizations like CGIAR (25 articles) and CIP (19 articles). Notable West 
African institutions are primarily located in Nigeria (National Root Crops Research 
Institute, University of Ibadan, Michael Okpara University of Agriculture, Rufus Giwa 
Polytechnic, Adekunle Ajasin University, Landmark University, University of Benin) and 
Ghana (Council of Scientific & Industrial Research, University of Ghana, University of 
Cape Coast, University for Development Studies, Kwame Nkrumah University of Science 
and Technology), and to a lesser extent in the Ivory Coast (Universite Felix Houphouet 
Boigny) and Benin (University of Parakou). Additionally, organizations engaged in sweet 
potato research in West Africa were found outside the region, including in France 
(CIRAD) and Sweden (Swedish University of Agricultural Sciences). 

 

Figure 8. Studies on sweet potato in West Africa—top ten affiliations. CSIR: The Council of Scientific 
and Industrial Research; CGIAR: Consultative Group for International Agricultural Research. 
Figure 8. Studies on sweet potato in West Africa—top ten affiliations. CSIR: The Council of Scientific
and Industrial Research; CGIAR: Consultative Group for International Agricultural Research.

The findings concerning institutional affiliations correspond with those of the countries
of affiliation (Figure 9). Indeed, the leading countries are Nigeria (60 articles, 48.00%) and
Ghana (40 articles, 32.00%). Other notable West African countries in the research field are
Benin (8 articles), the Ivory Coast (7 articles), Burkina Faso (6 articles), and Sierra Leone
(4 articles). Furthermore, numerous authors are connected to institutions based beyond
West Africa, in Africa (e.g., Tanzania, Uganda, South Africa, Kenya, Senegal, Cameroon),
Europe (e.g., France, England, Germany, Sweden, Italy, Belgium), Asia (e.g., Malaysia,
Syria, Bangladesh), North America (e.g., USA, Canada), Latin America (e.g., Peru), and
Oceania (e.g., Australia). The 125 selected publications were authored by scholars and
researchers based in 40 countries and regions.

The analysis of the bibliographical data reveals that the primary sources of funding
are outside West Africa and even Africa, specifically international foundations (viz. Bill &
Melinda Gates Foundation) and research organizations (viz. CGIAR, International Potato
Centre). Some studies have been funded through West African institutions, either national
(e.g., CSIR Crops Research Institute Ghana, Tertiary Education Trust Fund Nigeria) or
regional ones (e.g., CORAF). Further research activities have received funding from African
institutions such as the African Union and the African Potato Association (APA). Moreover,
funding has been provided by some European foundations (e.g., Agropolis Foundation)



Agronomy 2025, 15, 766 10 of 32

and agencies (e.g., Department for International Development of the UK). Consequently,
the results underscore the insufficient domestic funding for sweet potato research in West
Africa, potentially hindering the development of domestic research endeavours.

Agronomy 2025, 15, x FOR PEER REVIEW 11 of 35 
 

 

The findings concerning institutional affiliations correspond with those of the 
countries of affiliation (Figure 9). Indeed, the leading countries are Nigeria (60 articles, 
48.00%) and Ghana (40 articles, 32.00%). Other notable West African countries in the 
research field are Benin (8 articles), the Ivory Coast (7 articles), Burkina Faso (6 articles), 
and Sierra Leone (4 articles). Furthermore, numerous authors are connected to institutions 
based beyond West Africa, in Africa (e.g., Tanzania, Uganda, South Africa, Kenya, 
Senegal, Cameroon), Europe (e.g., France, England, Germany, Sweden, Italy, Belgium), 
Asia (e.g., Malaysia, Syria, Bangladesh), North America (e.g., USA, Canada), Latin 
America (e.g., Peru), and Oceania (e.g., Australia). The 125 selected publications were 
authored by scholars and researchers based in 40 countries and regions. 

 

Figure 9. Studies on sweet potato in West Africa—top ten countries. 

The analysis of the bibliographical data reveals that the primary sources of funding 
are outside West Africa and even Africa, specifically international foundations (viz. Bill & 
Melinda Gates Foundation) and research organizations (viz. CGIAR, International Potato 
Centre). Some studies have been funded through West African institutions, either national 
(e.g., CSIR Crops Research Institute Ghana, Tertiary Education Trust Fund Nigeria) or 
regional ones (e.g., CORAF). Further research activities have received funding from 
African institutions such as the African Union and the African Potato Association (APA). 
Moreover, funding has been provided by some European foundations (e.g., Agropolis 
Foundation) and agencies (e.g., Department for International Development of the UK). 
Consequently, the results underscore the insufficient domestic funding for sweet potato 
research in West Africa, potentially hindering the development of domestic research 
endeavours. 

3.2. Geography of the Research on Sweet Potato in West Africa 

Studies on sweet potatoes exhibit considerable variation throughout West Africa 
(Table 1). A handful of nations, including Nigeria and Ghana—which lead the affiliation 
rankings—have conducted most of the studies. In fact, Nigeria and Ghana account for 
almost three-quarters of all studies on sweet potatoes in West Africa. Nigeria tops the list 
with the highest number of studies on sweet potatoes (59 articles, representing 47.2% of 
the total), followed by Ghana (31 articles, 24.8%). The significant number of studies from 
Nigeria, due to its large and populous nature and it being one of the largest producers of 

Figure 9. Studies on sweet potato in West Africa—top ten countries.

3.2. Geography of the Research on Sweet Potato in West Africa

Studies on sweet potatoes exhibit considerable variation throughout West Africa
(Table 1). A handful of nations, including Nigeria and Ghana—which lead the affiliation
rankings—have conducted most of the studies. In fact, Nigeria and Ghana account for
almost three-quarters of all studies on sweet potatoes in West Africa. Nigeria tops the list
with the highest number of studies on sweet potatoes (59 articles, representing 47.2% of
the total), followed by Ghana (31 articles, 24.8%). The significant number of studies from
Nigeria, due to its large and populous nature and it being one of the largest producers of
sweet potatoes worldwide, is somewhat anticipated, while the research output of Ghana
could suggest a noteworthy dynamism in its research landscape. Other countries in
West Africa with notable contributions include Burkina Faso (6 articles), the Ivory Coast
(5 articles), and Sierra Leone (6 articles). Conversely, many West African nations lack
sufficient coverage in this research area. For example, some countries—including Cabo
Verde and Senegal—have only produced one study on sweet potatoes. Additionally, about
half of the West African nations (8 out of 16)—viz. Gambia, Guinea, Guinea-Bissau, Liberia,
Mali, Mauritania, Niger, and Togo—have not been specifically studied concerning sweet
potatoes, reflecting a considerable research deficiency in this domain.

There is a general deficiency of thorough research on sweet potatoes covering the
entire West African region, with a few notable exceptions. For instance, Mourtala et al. [49]
evaluated new hybrids of sweet potato under drought conditions in Niger and Nigeria.
Adekambi et al. [50] tested whether the uptake of OFSP, rich in vitamin A, improved the
level of dietary diversity in households in Ghana and Nigeria. The limited number of
regional studies may suggest a lack of collaboration among West African nations concerning
sweet potato research.



Agronomy 2025, 15, 766 11 of 32

Table 1. Geography of studies on sweet potato in West Africa.

Country or Region
(Articles Number) * Documents

Benin (3) Ahoudou et al. [51]; Sanoussi et al. [52]; Sohindji et al. [53]

Burkina Faso (6) Ouédraogo et al. [54]; Sawadogo et al. [55]; Somé et al. [56]; Some et al. [57];
Tibiri et al. [58]; Tibiri et al. [59]

Cabo Verde (1) Nascimento [60]

Côte d’Ivoire/Ivory Coast (5) Koffi et al. [61]; Kouassi et al. [62]; Mahyao et al. [63]; Jean Maurel et al. [64];
Tetchi et al. [65]

Gambia (0)

Ghana (31)

Acheampong et al. [66]; Adekambi et al. [67]; Adom et al. [68];
Adu-Kwarteng et al. [69]; Akomeah et al. [70]; Amagloh et al. [71];
Amenyenu et al. [72]; Atuna et al. [73]; Atuna et al. [74]; Ayensu et al. [75];
Ayensu et al. [76]; Baafi et al. [77]; Baafi et al. [78]; Bonsi et al. [79]; Bonsi et al.
[80]; Carey et al. [81]; Darko et al. [82]; Donkor et al. [83]; Dziedzoave et al.
[84]; Etwire et al. [85]; Hormenoo et al. [86]; Kubuga et al. [87]; Lartey et al.
[88]; Morrison and Twumasi [89]; Otoo et al. [90]; Quayson and Ayernor [91];
Sossah et al. [92]; Sugri et al. [93]; Swanckaert et al. [94]; Tortoe et al. [95];
Younge et al. [96]

Nigeria (59)

Adekiya et al. [97]; Adetola et al. [98]; Adeyonu et al. [99]; Agbede [100];
Agbede and Oyewumi [101]; Agbede and Oyewumi [102]; Agbede and
Oyewumi [103]; Agbede et al. [104]; Aiyelaagbe and Jolaoso [105];
Aladesanwa and Adigun [106]; Alalade et al. [107]; Anikwe and Ubochi [108];
Anioke et al. [109]; Anuebunwa [110]; Anyaegbunam et al. [111]; Chinenye
et al. [112]; Dania et al. [113]; Ebem et al. [114]; Ebeniro et al. [115]; Ejike et al.
[116]; Ekwe et al. [117]; Etela et al. [118]; Farayola et al. [119]; Iheme et al.
[120]; Just et al. [121]; Lagerkvist et al. [122]; Larbi et al. [123]; Lawal et al.
[124]; Law-Ogbomo and Ikpefan [125]; Law-Ogbomo and Osaigbovo [126];
Mafulul et al. [127]; Meludu [128]; Nayan et al. [129]; Njoku et al. [130];
Nnam [131]; Nnam [132]; Nta et al. [133]; Nwinyi [134]; Nwokocha et al.
[135]; Odebode [136]; Odebode et al. [137]; Ogbalu [138]; Ogbonna et al. [139];
Ohizua et al. [140]; Ojimelukwe et al. [141]; Okorie et al. [142]; Okpara et al.
[143]; Okungbowa and Osagie [144]; Oloniyo et al. [145]; Olorunsogo et al.
[146]; Oshunsanya [147]; Oshunsanya [148]; Oyeogbe et al. [149]; Oyinloye
et al. [150]; Salau et al. [151]; Shourove et al. [152]; Winter et al. [153]; Yusuf
et al. [154]; Zuofa and Tariah [155]

Senegal (1) Thiam et al. [156]

Sierra Leone (6) Alghali and Bockarie [157]; Fereno et al. [158]; Kamara and Lahai [159];
Karim et al. [48]; Rhodes [160]; Williams et al. [161]

Western Africa ** (7)

Adekambi et al. [50]—Ghana and Nigeria; Adekambi et al. [162]—Ghana and
Nigeria; Dery et al. [163]—Ghana and Nigeria; Glato et al. [164]; Mourtala
et al. [49]—Niger and Nigeria; Peters [165]—Burkina Faso, Ghana and
Nigeria; Ssali et al. [166]—Ghana and Nigeria

Sub-Saharan Africa *** (6)
Abidin et al. [167]—Ghana and Malawi; Assefa et al. [168]—Ghana and
Ethiopia; Feukam Nzudie et al. [169]; Moyo et al. [170]—Ghana and Uganda;
Utoblo et al. [171]—Ghana and Malawi; Villordon et al. [172]

* No article specifically addresses the following Western African countries: Gambia, Guinea, Guinea-Bissau,
Liberia, Mali, Mauritania, Togo and Niger. ** Contains articles that focus on at least two countries in West Africa.
*** Contains articles that cover at least one country from another region in Africa outside of West Africa.

Further studies cover several sub-Saharan African countries, even from outside West
Africa. For instance, Utoblo et al. [171] analyzed the good practises and challenges encoun-
tered in the implementation of gender-responsive breeding of sweet potato and dissemi-
nation of selected varieties in Ghana and Malawi. Feukam Nzudie et al. [169] modelled
and forecasted losses of roots and tubers (e.g., cassava, potato, sweet potato, yam) and
estimated the resulting water losses in sub-Saharan Africa. Villordon et al. [172] used



Agronomy 2025, 15, 766 12 of 32

GIS-based tools and consensus modelling approaches to explore the distribution of the
germplasm of sweet potato in sub-Saharan Africa.

3.3. Agriculture Subsectors and Food Chain Stages

Regarding the agricultural subsectors, as expected, the majority of eligible studies
concentrate on crop production, considering that I. batatas is a crop, with a few excep-
tions [117,118,123]. Etela et al. [118] investigated the effects of adding fresh sweet potato
leaves to Guinea grass on milk yield in Bunaji and N’Dama cows during early lactation in
Nigeria. Larbi et al. [123] analyzed the yields of fodder and tubers as well as the fodder qual-
ity of 18 varieties of sweet potato at various stages of maturity in Nigeria. Ekwe et al. [117]
investigated the effects of sweet potato meal on the performance of weaner rabbits. This
result may suggest that sweet potatoes are not typically utilized in animal nutrition/feeding
or, alternatively, that there is a lack of studies on this topic in West Africa.

The production phase is significantly the most discussed part of the food chain, followed
by processing and consumption; in contrast, intermediate stages, particularly marketing
and distribution, are often neglected in scholarly research (Table 2).

The research on production encompasses several studies that explored, among others,
the diversity of sweet potato cultivars/varieties and their performance across various
nations, including Benin [52,53], Ghana [78,90,93,94], Niger [49], Nigeria [49,114], and
Burkina Faso [57], as well as West Africa [164] and the whole of sub-Saharan Africa [172].
For instance, Ebem et al. [114] evaluated 41 genotypes of sweet potato in diverse Nigerian
environments. Ejike et al. [116] analyzed the involvement of youth in the production of
sweet potato in Abia State (Nigeria) and found that the main constraints relate to motivation,
access to credit, and access to information from extension services.

A number of studies have examined the processing of sweet potatoes. For example,
Meludu [128] shed light on the various strategies that can be deployed for the establishment
of sweet potato’s cottage industry in Nigeria. The various processing and preparation meth-
ods include fermentation [154], boiling [62,141,170], frying [62,163,166], sun-drying [144],
oven-drying [141], roasting [141], mashing [62], and stewing [62]. Kouassi et al. [62] point
out that the main ways of preparing the roots of sweet potatoes in central and northern Ivory
Coast are frying, boiling, mashing, and stewing. Referring to the production of sweet potato
spari in southwest Nigeria, Odebode [136] state that “Processing methods include peeling,
grating, pressing, sieving, drying and packaging” (p. 418). Sweet potatoes have been utilized in
the production of flour [69,75,84,95,96,98,131,132,140,145,161], starch [65,135], biscuits [75],
chips [112], muffins [158,161], bread [69,79], noodles [69,146], yoghurt [83], and Gari [74].
Referring to the sweet potato promotion programme in Ghana, Adu-Kwarteng et al. [69]
pointed out that the analyzed genotypes have numerous potential uses and applications
in the food sector; these applications encompass fufu flour, bread, pastries, French fries,
gluten-free noodles, yoghurt filler, baby food, juices, and raw materials for breweries and
various other industries. This shows that sweet potato has a huge industrial potential.

Meanwhile, there is a restricted amount of research concentrating on the marketing of
sweet potato and its related products. For example, Anyaegbunam et al. [111] investigated
market integration and difficulties related to sweet potato marketing in southeastern
Nigeria; they found that the main difficulties in sweet potato marketing comprise the lack
of credit and banking facilities, inappropriate market infrastructure and stalls, high cost of
transportation, commodity bulkiness, and deficiency of storage facilities.

Regarding consumption, research has focused on sweet potato as an edible product and
its possible health benefits. The majority of articles in this field investigate sweet potato’s
role in food and nutrition security, with a particular focus on its contribution to addressing



Agronomy 2025, 15, 766 13 of 32

vitamin A deficiency. These studies encompass the utilization of sweet potatoes in the
fortification of foods.

Table 2. Stages of the food chain.

Food Chain Stage * Documents

Primary production

Acheampong et al. [66]; Adekambi et al. [50]; Adekambi et al. [67]; Adekiya et al.
[97]; Adeyonu et al. [99]; Adom et al. [68]; Agbede [100]; Agbede and Oyewumi
[101]; Agbede and Oyewumi [102]; Agbede and Oyewumi [103]; Agbede et al. [104];
Ahoudou et al. [51]; Aiyelaagbe and Jolaoso [105]; Akomeah et al. [70]; Aladesanwa
and Adigun [106]; Alalade et al. [107]; Alghali and Bockarie [157]; Amenyenu et al.
[72]; Anikwe and Ubochi [108]; Assefa et al. [168]; Atuna et al. [73]; Baafi et al. [77];
Bonsi et al. [79]; Carey et al. [116]; Dania et al. [113]; Darko et al. [82]; Dziedzoave
et al. [84]; Ebem et al. [114]; Ebeniro et al. [115]; Ejike et al. [116]; Etwire et al. [85];
Feukam Nzudie et al. [169]; Glato et al. [164]; Hormenoo et al. [86]; Kamara and
Lahai [159]; Karim et al. [48]; Kouassi et al. [62]; Larbi et al. [123]; Lawal et al. [124];
Law-Ogbomo and Ikpefan [125]; Law-Ogbomo and Osaigbovo [126]; Mahyao et al.
[63]; Mourtala et al. [49]; Nayan et al. [129]; Njoku et al. [130]; Nwinyi [134]; Ogbalu
[138]; Ogbonna et al. [139]; Ojimelukwe et al. [141]; Okorie et al. [142]; Okpara et al.
[143]; Oshunsanya [147]; Oshunsanya [148]; Otoo et al. [90]; Oyeogbe et al. [149];
Peters [165]; Rhodes [160]; Sanoussi et al. [52]; Sawadogo et al. [55]; Sohindji et al.
[53]; Some et al. [57]; Sossah et al. [92]; Sugri et al. [93]; Swanckaert et al. [94]; Tibiri
et al. [58]; Tibiri et al. [59]; Utoblo et al. [171]; Villordon et al. [172]; Winter et al.
[153]; Zuofa and Tariah [155]

Processing (including
postharvest storage)

Abidin et al. [167]; Adetola et al. [98]; Adu-Kwarteng et al. [69]; Alalade et al. [107];
Atuna et al. [73]; Atuna et al. [74]; Ayensu et al. [75]; Bonsi et al. [79]; Carey et al.
[81]; Chinenye et al. [112]; Dery et al. [163]; Donkor et al. [83]; Dziedzoave et al. [84];
Etwire et al. [85]; Fereno et al. [158]; Feukam Nzudie et al. [169]; Kouassi et al. [62];
Meludu [128]; Moyo et al. [170]; Nnam [131]; Nnam [132]; Nta et al. [133];
Nwokocha et al. [135]; Odebode [136]; Odebode et al. [137]; Ohizua et al. [140];
Ojimelukwe et al. [141]; Okungbowa and Osagie [144]; Oloniyo et al. [145];
Olorunsogo et al. [146]; Ouédraogo et al. [54]; Ssali et al. [166]; Sugri et al. [93];
Tetchi et al. [65]; Tortoe et al. [95]; Williams et al. [161]; Younge et al. [96]; Yusuf et al.
[154]

Marketing and distribution Alalade et al. [107]; Anyaegbunam et al. [111]; Carey et al. [81]; Farayola et al. [119];
Mahyao et al. [63]; Peters [165]

Consumption

Adekambi et al. [50]; Adekambi et al. [67]; Adekambi et al. [162]; Adetola et al. [98];
Amagloh et al. [71]; Bonsi et al. [79]; Bonsi et al. [80]; Carey et al. [81]; Dery et al.
[163]; Donkor et al. [83]; Fereno et al. [158]; Hormenoo et al. [86]; Iheme et al. [120];
Just et al. [121]; Koffi et al. [61]; Kubuga et al. 87]; Lagerkvist et al. [122]; Lartey et al.
[88]; Mafulul et al. [127]; Jean Maurel et al. [64]; Morrison and Twumasi [89]; Moyo
et al. [170]; Nnam [132]; Odebode [136]; Oloniyo et al. [145]; Oyinloye et al. [150];
Peters [165]; Rhodes [160]; Salau et al. [151]; Sanoussi et al. [52]; Shourove et al.
[152]; Somé et al. [56]; Ssali et al. [166]; Thiam et al. [156]; Utoblo et al. [171];
Williams et al. [162]; Younge et al. [96]

* A number of documents discuss different stages of the food chain.

Some researchers take a broader perspective, looking at various stages of the food
supply chain or value chain [81,141,161,165]. For instance, Ojimelukwe et al. [141] analyzed
the effects of soil nutrient management methods (cf. production)—namely poultry ma-
nure, Agrolyser, and NPK—and preparation/cooking methods (cf. processing) on nutrient
content and the phytochemical composition of OFSP in Umudike (Abia State, Nigeria).
Williams et al. [161] evaluated the sensory quality characteristics of different muffins from
sweet potato flours, thus addressing both processing and consumption. Carey et al. [81]
delineated an integrated approach for the development and deployment of non- or low-
sweet potato cultivars in Ghana that addresses aspects relating to production, processing,
marketing, and consumption. Peters [165] provided an overview of the development of the



Agronomy 2025, 15, 766 14 of 32

value chain of sweet potato in West Africa (Ghana, Nigeria, and Burkina Faso), spanning
from production to consumption through marketing.

Sweet potatoes are cultivated in various agricultural systems, both through monocrop
and intercropping methods, including agroforestry [48,105]. They have been intercropped
with several crops, such as maize in Nigeria [129,149,155], eggplant in Nigeria [115], okra
in Nigeria [130], and papaya in Nigeria [105]. This highlights the crop’s flexibility in
intercropping across diverse environments and farming practises.

In terms of production, some research focuses on fertilization and pest control, while
irrigation is typically overlooked (Table 3). Further agronomic practises tested also included
foliage/shoot removal [72,134].

Table 3. Agronomic practises explored in research related to sweet potato cultivation.

Agronomic Practice * Documents

Fertilization and soil fertility
management

Adekiya et al. [97]; Agbede [100]; Agbede and Oyewumi [101]; Agbede and
Oyewumi [102]; Agbede et al. [104]; Atuna et al. [73]; Darko et al. [82]; Kamara
and Lahai [159]; Lawal et al. [124]; Law-Ogbomo and Ikpefan [125];
Law-Ogbomo and Osaigbovo [126]; Ojimelukwe et al. [141]; Okpara et al. [143];
Sugri et al. [93]

Pest management
(including weeds)

Adom et al. [68]; Agbede and Oyewumi [101]; Alghali and Bockarie [157];
Anioke et al. [109]; Anuebunwa [110]; Dania et al. [113]; Hormenoo et al. [86];
Nascimento [60]; Nayan et al. [129]; Nta et al. [133]; Ogbalu [138]; Sossah et al.
[92]; Sugri et al. [93]; Tibiri et al. [58]; Tibiri et al. [59]; Zuofa and Tariah [155]

Irrigation Assefa et al. [168]; Mourtala et al. [49]; Sawadogo et al. [55]
* Several documents discuss different agronomic practises.

Typically, there is a scarcity of research focused on irrigation practises for sweet pota-
toes, with only a few notable exceptions. For example, Mourtala et al. [49] evaluated
twenty-three hybrids of sweet potato under drought and irrigation conditions in four
locations in Niger and two locations in Nigeria. Sawadogo et al. [55] used satellite remote
sensing-derived indicators (e.g., crop water productivity) to assess the performance of
irrigation of different crops, including sweet potatoes, in the Kou Valley Irrigation Scheme
in Burkina Faso.

Research related to pest management encompasses various pests and diseases, such
as sweet potato weevils (Cylas spp.) in Ghana [68] and Nigeria [114,133], Lepidopterous
Acraea acerata in Nigeria [109,138], soft rot disease caused by Rhizopus in Nigeria [113],
millipede (Bandeirenica caboverdus) in Cape Verde [60], SPFMV in Burkina Faso [58,59] and
Ghana [92], SPCSV in Burkina Faso [58,59], CMV in Ghana [92], SPCFV in Ghana [92],
SPCV in Ghana [92], SPLCV in Ghana [92] and Burkina Faso [59], SPMMV in Ghana [92],
SPMSV in Ghana [92], and SPVG in Ghana [92]. For instance, Adom et al. [68] analyzed the
susceptibility of seven Ghanaian improved varieties to the sweet potato weevil (Cylas spp.)
in the coastal savanna zone of Ghana. Sossah et al. [92] assessed the incidence of various
viruses in 20 accessions of sweet potato in Ghana. Furthermore, certain studies have
addressed weed management in countries such as Ghana [86]. Sweet potato has also been
used as an intercrop or a live mulch to control weeds, especially in Nigeria [106,110,129,155].

Numerous articles explore the fertilization of sweet potato as well as soil fertility man-
agement concerning this crop. Indeed, research on this topic has been conducted through-
out West Africa in countries such as Nigeria [97,100–104,124–126,143], Ghana [73,82], and
Sierra Leone [159]. For instance, Agbede and Oyewumi [103] examined the impacts of dif-
ferent levels of biochar and poultry manure on sweet potato growth and yield as well as of
soil physical and chemical qualities in southwestern Nigeria. Darko et al. [82] assessed the
effects of fertilizer application rates on the productivity of sweet potato in different agroe-



Agronomy 2025, 15, 766 15 of 32

cological zones in Ghana. Additionally, the application of sweet potato in intercropping is
another approach to dealing with fertilization and soil fertility management.

Different parts of sweet potato, such as the tubers/roots and leaves, were the subjects of
the selected research (Table A4). Depending on the area of interest, various parts of the plant
have been investigated. Studies focusing on sweet potato as a leafy green primarily concen-
trate on the leaves. Conversely, research that involves the processing and examination of the
properties of processed products generally focuses on tubers. However, some agronomy-
related articles address the sweet potato plant as a whole. Additionally, certain studies ex-
plore several parts of the sweet potato simultaneously. This includes multiple investigations
that examined the diversity of sweet potatoes and/or the performances of different vari-
eties/cultivars/clones in various West African countries [52,53,57,78,90,93,94,114,164,172].

3.4. Climatic and Ecosystemic Resilience

Only some papers address the potential of sweet potatoes in tackling numerous
environmental issues in Western Africa, including changing climate and degrading land.

Overall, the academic literature regarding sweet potatoes in Western Africa gives
insufficient attention to climate change and climate variability. Some research has explored
the relationship between sweet potato and climate change in Western Africa. For instance,
Glato et al. [164] assessed the diversity of the species in West Africa by collecting samples
from a region that stretches from coastal Togo to Sahelian Senegal, encompassing various
climatic conditions; they concluded that the genetic diversity of sweet potatoes in West
Africa is organized into multiple groups, with certain groups being found in very distinct
climatic environments, such as those under a tropical humid climate or a Sahelian climate.
Meanwhile, Feukam Nzudie et al. [169] modelled the effects of climate variables on losses
of roots and tubers (e.g., cassava, potato, sweet potato, yam) as well as the resulting water
losses in sub-Saharan Africa. They found that in 2025, the magnitude of root and tuber
losses is expected to increase by 27.72% from 2013 levels for West Africa. This implies that
water losses will also increase; so, measures aimed at preventing root and tuber losses will
also lessen the pressure on available water resources. In this context of changing climate,
it is important to pay particular attention to the storage of sweet potatoes; sand storage
technology seems promising for drought-prone areas and can help mitigate the climate
change effects [167].

A dearth of studies dealt with the drought tolerance of sweet potatoes in various
Western African countries such as Niger [49] and Nigeria [49]. However, Mourtala et al. [49]
claim that while Western Africa is a dry region, no drought-tolerant variety of sweet potato
was registered. If this is confirmed, it implies that sweet potato is not particularly adapted to
rainfed cultivation in arid and semi-arid regions of Western Africa, such as the Sahel region.

Likewise, as for climate change, the importance of sweet potatoes in mitigating land
degradation has generally been neglected in the existing literature. However, some articles
discuss its role in sustaining or improving soil fertility. It seems that sweet potato crop
can be used as a soil conservation strategy [139] and can be employed in conservation
agriculture [168]. Moreover, some sweet potato cultivars/genotypes have been adapted
to different environments and agroecological zones [94,114]. Thus, sweet potato holds the
potential to serve as a valuable resource in marginal agroecosystems. However, harvesting
sweet potatoes can contribute to fertile topsoil loss and removal [148].

3.5. Food Security and Nutrition

Research shows that sweet potato has considerable potential to enhance food security
and nutritional well-being in West Africa by improving food availability, accessibility, and
dietary diversity and quality.



Agronomy 2025, 15, 766 16 of 32

The existing literature on sweet potatoes in West Africa briefly addresses the as-
pect of food availability. Nevertheless, the limited studies available imply that sweet
potato serves as a significant food source for households across West Africa. The
presence of sweet potato and its derivatives is contingent upon crop yield. In this
context, various studies indicate that sweet potato yield is influenced by factors such
as cultivar/accession [49,57,62,68,78,82,90,94,101,114,124,142], harvesting and maturity
stage [123], and agronomic techniques (e.g., fertilization/soil nutrient management, pest man-
agement, weeding, irrigation) [49,58,68,72,82,93,97,100,103,104,108,124–126,134,141,143]. In
addition to yield, the market availability of sweet potatoes is also reliant on the effective
management of postharvest and storage losses [62,68,73,133,167].

Although research on sweet potatoes in West Africa concerning food access has been lim-
ited, findings reveal that households with access to sweet potatoes experience better food
security and nutrition, particularly among lower-income families. Iheme et al. [120] showed
that the price of sweet potato increased dramatically in Nigeria during the COVID-19 lock-
down, which negatively affected its financial accessibility and affordability for Nigerians.
Sweet potato cultivation in the urban and peri-urban regions of countries, like the Ivory
Coast [63], facilitates better access to this valuable nutrient source for city residents. Value
addition increases the income of sweet potato farmers, as shown in Kwara State (Nige-
ria) [107], which can provide them with additional financial resources and improve their
access to food. However, the impact of sweet potatoes on food security and food access is
dependent on market access [107].

Most articles discussing food security in relation to sweet potatoes concentrate on
their nutritional role in the population’s diets, with a focus on food utilization. Numerous
authors emphasize the exceptional nutritional composition, quality, and profile of sweet
potatoes [50,52,56,57,67,71,79,145,154,162] to support their promotion as a solution to ad-
dressing nutrition-related issues, especially micronutrient deficiencies. Apart from tubers,
sweet potato leaves have also shown an interesting nutritional profile [71,80]. Sweet potato
is abundant in vitamins, particularly vitamin A [56,145,154]. In this regard, substantial
focus has been placed on orange-fleshed sweet potato, known for its high beta-carotene or
pro-vitamin A content (Table 4). Interventions and projects using sweet potatoes, espe-
cially orange-fleshed sweet potatoes, to address malnutrition among the population have
been reported in several West African countries such as Ghana [79,87,162], Senegal [156],
the Ivory Coast [64], and Nigeria [98,121,122,162]. These regarded mainly women [156]
and infants and children [64,98,121,122,156]. Dark sweet potato varieties also have a
high iodine content [151]. The nutritional value and nutrient content of sweet potato,
including its pro-vitamin A levels, can be influenced by various factors/variables such
as cultivar/variety [56,57,84,95], agronomic and postharvest practises [72,73,81,102], and
processing, cooking, and preparation techniques [141,154].

The incorporation of sweet potato in fortification/supplementation programmes in nu-
merous West African nations [79,146] is attributed to its outstanding nutrient composition
and nutritional profile. Sweet potato has been utilized as a dietary addition in flours such
as cassava in Ghana [74,96], porridges from processed sorghum and Bambara groundnut in
Nigeria [132], bread in Ghana [79], noodles in Nigeria [146], and biscuits in Ghana [75,76].

Ensuring food safety is crucial for optimizing food utilization. Some studies have
indicated that sweet potatoes (tubers and leaves) and their derivatives may harbour heavy
metals [127] and pesticide/herbicide residues [86,150], which could potentially threaten
human health and wellness. Research revealing these potential health risks has been carried
out in countries such as Nigeria [127,150] and Ghana [86].



Agronomy 2025, 15, 766 17 of 32

Table 4. Research on orange-fleshed sweet potato in West Africa.

Article Country Topic

Abidin et al. [167] Ghana and Malawi Sand storage
Adekambi et al. [50] Ghana and Nigeria Adoption of orange-fleshed sweet potatoes

Adekambi et al. [162] Ghana and Nigeria Effect of orange-fleshed sweet potato adoption on
household dietary diversity

Adekambi et al. [67] Ghana Adoption of orange-fleshed sweet potatoes
Adetola et al. [98] Nigeria Sweet potato-based complementary foods

Amagloh et al. [71] Ghana Nutrient contents of dark green leafy vegetables
Atuna et al. [73] Ghana Effect of soil amendment on postharvest quality

Atuna et al. [74] Ghana Physicochemical and functional properties of cassava
and orange-fleshed sweet potato gari

Ayensu et al. [75] Ghana Acceptability of biscuits fortified with orange-fleshed
sweet potato among pregnant women

Ayensu et al. [76] Ghana Orange-fleshed sweet potato-enriched biscuits

Bonsi et al. [79] Ghana Nutritional composition and acceptance by consumers of
breads from the puree of orange-fleshed sweet potato

Bonsi et al. [80] Ghana Production, recipes, and consumption of sweet potato

Carey et al. [81] Ghana Development and deployment of non- and low-sweet
cultivars

Dery et al. [163] Ghana and Nigeria Consumer segmentation and sensory characteristics of
fried sweet potatoes

Etwire et al. [85] Ghana Adoption of good agricultural practises and innovations
Just et al. [121] Nigeria Consumption of biofortified food by schoolchildren
Koffi et al. [61] Ivory Coast Healing of hard-to-heal wounds

Kubuga et al. [87] Ghana Nutrient contribution in community-based infant foods
Lagerkvist et al. [122] Nigeria School intervention with biofortified sweet potato meals

Ojimelukwe et al. [141] Nigeria Effects of nutrient management and cooking on
phytochemical and nutrient composition

Okpara et al. [143] Nigeria Nitrogen fertilization
Oloniyo et al. [145] Nigeria Biochemical and antioxidant properties

Peters [165] West Africa (Burkina Faso,
Ghana, Nigeria) Sweet potato value chain

Sanoussi et al. [52] Benin Diversity of sweet potato landraces
Sohindji et al. [53] Benin Breeding

Some et al. [57] Burkina Faso Breeding

Thiam et al. [156] Senegal Dietary intakes and nutritional status of mother–child
pairs in rural areas

Tortoe et al. [95] Ghana Amylopectin in sweet potato varieties
Younge et al. [96] Ghana Characterization of flours from cassava and OFSP

Yusuf et al. [154] Nigeria Effect of traditional processing methods on the nutrient
content

A limited number of the selected articles address claims regarding the health advan-
tages of sweet potatoes [61,64,88,152]. Koffi et al. [61] found that diet supplementation
with the orange-fleshed sweet potato accelerates the healing of hard-to-heal wounds in
the Ivory Coast. Jean Maurel et al. [64] argued that the diversification of food thanks to
sweet potato has a positive effect on the prognostic inflammatory and nutritional index
(PINI) among school-age children in the Ivory Coast. Lartey et al. [88] reported that sweet
potato tubers are commonly used in Ghana in the management of erectile dysfunction.
Meanwhile, Shourove et al. [152] found that the occurrence of anemia was lower among
Nigerian children fed vegetables such as sweet potato, pumpkin, carrot, and squash.

There is no dedicated article that addresses the connection between food security and
stability. However, it is essential to emphasize the role of sweet potatoes in sustaining
the population during times of food shortages. This, in turn, can aid in maintaining the
consistency of food supply despite the challenges posed by climate change. However,
climate change can increase the losses of roots and tubers (e.g., potato, cassava, sweet
potato, yam) in sub-Saharan Africa [169], which might jeopardize the stability of food
production and supply. Furthermore, the instability of some cultivars [49] might determine
the variation in yield and, consequently, production from one year to another. Meanwhile,
Some et al. [57], referring to the breeding of sweet potato in Burkina Faso, postulated that



Agronomy 2025, 15, 766 18 of 32

“increased storage root yield improvement would be slow” (p. 69). Genetic instability can also
affect the nutritional value and nutrient contents of sweet potato clones/cultivars [70].

3.6. Socio-Economic Impacts and Livelihoods

The literature regarding sweet potatoes in West Africa covers various social and eco-
nomic aspects. The findings from the bibliometric analysis support the assumption that the
predominant focus within this research area lies in biological and environmental sciences,
while social sciences and economics have received inadequate attention. Nonetheless, the
analysis of the scholarly works on sweet potatoes in Western Africa concerning the SDGs
indicated that SDG 2 and SDG 03, which pertain to the socio-economic domain, are the most
prominently addressed goals. Meanwhile, other SDGs related to socio-economic issues,
such as SDG 01 (No Poverty) and SDG 05 (Gender Equality), have received only limited
coverage. Some research indicates that sweet potatoes can have a beneficial effect on local
communities, particularly among smallholders, by aiding in the generation of income, the
empowerment of women, and the enhancement of rural livelihoods. Nevertheless, the
number and scope of these studies are quite limited.

Sweet potato is viewed as a vital source of livelihood and income across numerous West
African countries. In fact, some researchers consider sweet potatoes to hold substantial eco-
nomic significance in various West African nations, including Ghana [93], Nigeria [111] and
Ivory Coast [63]. Several studies have shown the profitability of sweet potato [63,93,139].
Considering both return on investments and benefit–cost ratio, several sweet potato va-
rieties were found to be economically viable in northern Ghana [93]. Sweet potato was
also profitable as a soil conservation strategy in Abia State, Nigeria [139]. The use of
sweet potatoes as an intercrop or a live mulch with different crops, such as maize, was
financially viable in Nigeria [106,110,155]; indeed, it contributed to weed control and sup-
pression, thus reducing production costs and increasing the income of farmers. Sweet
potatoes represent an important source of livelihood for youth; Ejike et al. [116] found that
youths were highly involved in the production of sweet potatoes in Abia State, Nigeria.
Furthermore, intercropping sweet potatoes with cereals can stabilize farmers’ incomes;
Oyeogbe et al. [149] concluded that the intercropping of maize with sweet potato and/or
cowpea in the tropical rainforest agroecosystem of Nigeria can meet the food, nutrition,
and income stability of farmers. Etela et al. [118] posited that fresh sweet potato foliage
can be utilized for the whole or partial replacement of costly cottonseed meal or dried
brewers’ grains in the diets of lactating cows in Nigeria to save costs, thus increasing the
income of cow breeders. Furthermore, sweet potatoes could offer prospects for diversifying
income-generating endeavours and creating jobs through processing [69,83,107,128,137].
Alalade et al. [107] found that producers in Kwara State (Nigeria) engaged in value-adding
activities had higher incomes from sweet potatoes than those that sold the raw produce at
the farm gate.

The significance of sweet potatoes for poor individuals, including smallholders, is
considerable. This crop is typically grown by small-scale and economically disadvantaged
farmers. Sweet potato is mostly grown on small plots of land (less than 1 ha) in central
and northern Ivory Coast [62] and western Nigeria [119]. Sweet potato’s relevance and
versatility make it a good component of agricultural development projects and programmes,
especially those addressing food insecurity and malnutrition [50,79,156].

Certain studies suggest that sweet potatoes may contribute to promoting gender em-
powerment. In fact, various analyses indicate that women are widely involved in the
value chains (cultivation, processing, and marketing) of sweet potatoes and their prod-
ucts in several countries like the Ivory Coast [62,63] and Nigeria [136]. Kouassi et al. [62]
found that women represent the majority of sweet potato producers (66%) in the central



Agronomy 2025, 15, 766 19 of 32

and northern Ivory Coast. Mahyao et al. [63] underscored that the market supply chains
of sweet potato leaves in Yamoussoukro and Abidjan (Ivory Coast) are dominated by
women (97.5% in Abidjan and 100% in Yamoussoukro). Studies addressing gender in
relation to sweet potatoes have been performed in several Western African countries such
as Ghana [66,75,80,85,171], Ivory Coast [62,63], and Nigeria [136]. They cover diverse topics
such as participatory breeding [62,171] and agricultural communication and extension [85].
Utoblo et al. [171] posit that the application of gender-responsive breeding and variety
dissemination practises resulted in the adoption and development of acceptable varieties
of sweet potatoes (including orange-fleshed sweet potato) in Ghana and Malawi. Ode-
bode [136] argues that the promotion of processed sweet potato products such as spari
could not only contribute to food security but also economic empowerment among rural
women in southwest Nigeria. However, Acheampong et al. [66] showed that the adoption
of improved sweet potato varieties significantly increased farmers’ income in Ghana but
underlined that men gained more advantages than women because they had better access
to extension services, enhanced varieties, and more productive resources.

The development of sweet potato value chains holds the promise of addressing various
issues and fostering long-term socio-economic development in Western Africa. Processing
underutilized crops such as sweet potatoes can enhance producers’ income, bolster food
security, and contribute to rural development.

4. Conclusions
West Africa appears to have a limited presence in the academic literature concerning

sweet potatoes. Additionally, research focusing on sweet potatoes in West Africa has only
emerged in recent years. The annual fluctuation in publication numbers suggests that inter-
est in this crop varies over time. The field of research is multidisciplinary but predominantly
revolves around biological sciences, with a scarce representation of economics and social
sciences. The literature examined connects to 11 SDGs, with the most prominent being SDG
02 and SDG 03. The articles selected for analysis feature authors from 174 different research
institutions and universities. Leading the list of affiliations are international organizations
like CGIAR and CIP. Notable West African institutions are primarily located in Nigeria and
Ghana, with lesser representation from the Ivory Coast and Benin. Furthermore, numerous
authors are connected to institutions outside West Africa. A considerable share of funding
for sweet potato research in West Africa comes from outside the region, particularly from
international foundations (such as the Bill & Melinda Gates Foundation) and research orga-
nizations (like CGIAR and CIP). This underlines the scarcity of domestic funding within
West Africa. Research on sweet potatoes varies greatly throughout Africa, with a handful
of countries, mainly Nigeria and Ghana, conducting most of research; they collectively
represent almost three-quarters of all sweet potato research in West Africa. In contrast,
half of the West African countries (8 out of 16) were not the focus of any dedicated sweet
potato research. Moreover, the limited number of regional studies may indicate a lack of
collaboration among West African nations concerning sweet potatoes.

In terms of agricultural subsectors, the chosen papers concentrate on crop production.
Production is overwhelmingly examined, followed by processing and consumption, while
marketing and distribution often receive minimal attention in the academic literature.
With regard to production, some studies explore fertilization and pest management, but
irrigation is frequently neglected. Only a few articles indexed on WoS address the potential
of sweet potatoes in tackling numerous environmental issues in West Africa, such as climate
change and land degradation. Academic research suggests that sweet potatoes can play a
role in guaranteeing food security and nutrition in Africa by improving food availability,
enhancing food accessibility, and improving dietary quality. However, most of the articles



Agronomy 2025, 15, 766 20 of 32

selected that link sweet potatoes to food security primarily focus on their nutritional
contributions, particularly highlighting food utilization and their role in mitigating vitamin
A deficiencies. A limited number of selected studies address the health advantages of sweet
potatoes. The body of literature surrounding sweet potatoes in West Africa pays scant
attention to social and economic elements. Some research indicates that sweet potatoes can
benefit local communities, especially smallholders, by aiding in income generation, rural
livelihoods, and gender empowerment. Nevertheless, these studies are few in number and
limited in scope.

Given the numerous validated benefits of the crop, it is essential to promote sweet
potatoes in West Africa to confront the various developmental challenges the region en-
counters. As suggested by Peters [165], possible measures to enhance the sweet potato
value chain in West Africa include the following: (i) the breeding or selection of high-yield
varieties that meet farmers as well as market and consumer preferences; (ii) implementing
optimal production and agronomic practises such as ridging and weeding techniques to
lower labour requirements, applying suitable fertilization and pest management methods,
and determining the most effective intercropping methods; and (iii) coordinating and
organizing farmers to improve their access to market to minimize the expenses and time
involved in individual marketing efforts. In this context, it is essential to conduct studies on
sweet potato in West Africa to tackle the existing challenges and limitations hindering its
promotion and development. Specifically, there is a necessity to enhance the understanding
of the crop’s genetic diversity to support breeding programmes and refine production spec-
ifications, along with effective agronomic practises (such as fertilization, pest management,
and irrigation) to be communicated and shared with producers/farmers. Research is also
vital for creating acceptable and cost-effective processing/transformation methods while
preserving the quality of sweet potato and complying with safety standards. Enhancements
in both quality and safety would boost the marketing and consumption of sweet potato,
particularly orange-fleshed varieties, which already enjoy a positive reputation among
researchers, policymakers, and the general public.

Author Contributions: Conceptualisation, H.E.B., F.G., I.D.G., J.N., L.D., R.A.S., R.K.N., S.R.F.T.,
V.-M.R., Z.K., and F.A; methodology, H.E.B.; software, H.E.B.; validation, H.E.B.; formal analysis,
H.E.B.; investigation, H.E.B.; resources, H.E.B.; data curation, H.E.B.; writing—original draft prepara-
tion, H.E.B., F.G., I.D.G., J.N., L.D., R.A.S., R.K.N., S.R.F.T., V.-M.R., Z.K., and F.A; writing—review
and editing, H.E.B., F.G., I.D.G., J.N., L.D., R.A.S., R.K.N., S.R.F.T., V.-M.R., Z.K., and F.A; visualization,
H.E.B.; project administration, H.E.B., L.D., J.N., F.G., and F.A.; funding acquisition, H.E.B., L.D., J.N.,
F.G., and F.A. All authors have read and agreed to the published version of the manuscript.

Funding: This research was funded by the DeSIRA initiative (Development Smart Innovation through
Research in Agriculture) of the European Union (contribution agreement FOOD/2021/422-681).

Institutional Review Board Statement: Not applicable.

Data Availability Statement: Data are contained within the article.

Acknowledgments: This work was carried out within the project SUSTLIVES (SUSTaining and
improving local crop patrimony in Burkina Faso and Niger for better LIVes and EcoSystems—
https://www.sustlives.eu).

Conflicts of Interest: The authors declare no conflicts of interest. The funders had no role in the
design of the study; the collection, analyses, or interpretation of data; the writing of the manuscript;
or the decision to publish the results.

https://www.sustlives.eu


Agronomy 2025, 15, 766 21 of 32

Abbreviations
The following abbreviations are used in this manuscript:

APA African Potato Association
CGIAR Consultative Group for International Agricultural Research
CIP International Potato Centre
CIRAD Agricultural Research Centre for International Development
CMV Cucumber mosaic virus
CORAF West and Central African Council for Agricultural Research and Development
CSIR Council of Scientific and Industrial Research
DRC Democratic Republic of the Congo
FAO Food and Agriculture Organisation of the United Nations
GIS Geographic Information Systems
NUS Neglected and Underutilised Species
SDGs Sustainable Development Goals
SLU Swedish University of Agricultural Sciences
SPCFV Sweet potato chlorotic fleck virus
SPCSV Sweet potato chlorotic stunt virus
SPCV Sweet potato collusive virus
SPLCV Sweet potato leaf curl virus
SPMMV Sweet potato mild mottle virus
SPMSV Sweet potato mild speckling virus
SPVG Sweet potato virus G
WoS Web of Science

Appendix A

Table A1. Production, area harvested, and yield of sweet potato in top 20 world countries and African
countries, 2022.

Country Production (t) Area Harvested (ha) Yield (kg/ha)

Top 20 world
countries

China 46,828,761.12 2,157,292 21,707.2
Malawi 8,051,118.37 335,783 23,977.1
Tanzania 4,259,619.65 576,196 7392.7
Nigeria 4,011,034.89 1508,514 2658.9
Angola 1,873,002 189,378 9890.3
Rwanda 1,372,745.21 189,435 7246.5
Uganda 1,337,511.74 314,250 4256.2
India 1,184,000 107,000 11,065.4
USA 1,176,483 53,500 21,990.3
Madagascar 1,132,742.12 133,334 8495.6
Ethiopia 1,000,575.96 43,685 22,904.4
Viet Nam 976,122.24 85,821 11,374
Indonesia 875,000 47,444 18,443
Brazil 847,100 58,229 14,547.7
Burundi 807,860.51 71,685 11,269.5
Japan 710,700 32,300 22,003.1
Papua New Guinea 710,120.73 139,026 5107.8
Kenya 650,000 47,468 13,693.5
Democratic Republic of
the Congo (DRC) 591,101 117,919 5012.8

Cameroon 579,883.47 89,010 6514.8



Agronomy 2025, 15, 766 22 of 32

Table A1. Cont.

Country Production (t) Area Harvested (ha) Yield (kg/ha)

Other African
countries

Mozambique 510,238 10,597 5340.4
Egypt 508,314.04 69 16,855.8
Mali 452,193 9880 11,698.2
Guinea 384,052.51 195 14,369.2
Sierra Leone 286,118.06 31,984 6816.4
Sudan 266,986.71 2250 4698.8
Niger 233,696.64 1278 7190.7
Chad 218,015 33,489 1752.3
Ghana 142,671.37 14,775 34,404.2
Zambia 132,442.12 19,218 5398.7
Burkina Faso 115,579.98 1336 1870.1
Senegal 110,600 2015 1943.1
Equatorial Guinea 103,749.32 78,340 1821.2
South Africa 87,647 73,153 5250
Zimbabwe 62,792.59 8155 4995.7
Côte d’Ivoire 58,684.14 2187 11,154.1
Benin 56,589.62 30,359 14,894.9
Guinea-Bissau 40,738.15 2782 1892.4
Liberia 24,393.55 115 15,295.7
Morocco 11,710 560 20,910.7
Comoros 10,572.29 83,646 6100
Togo 9919 7376 31,682.6
Congo 9190.5 2496 44,317.9
Somalia 8655.65 34,563 8278.1
Mauritania 5264.75 873 9917.9
Gabon 3915.14 33,008 2655.3
Cabo Verde 2802 -- --
Eswatini 2498.99 34,790 7674.3
Mauritius 1759 2738 3622.7
Botswana 1169.12 39,684 3337.4

Source: FAO [22].

Table A2. Earlier reviews dealing partially with sweet potatoes in West Africa retrieved from the
Web of Science database.

Review Publication Date Review Type Geographical
Coverage Thematic Focus

Howeler et al. [173] October 1993 Narrative Tropics Tillage systems for root and
tuber crops

Alegbejo [174] 2000 Narrative Nigeria Plant viruses transmitted by
whiteflies

Ohimain [175] June 2013 Narrative Nigeria Biofuel policy

De Moura et al. [176] 2015 Narrative Africa

Provitamin A carotenoids
retention in biofortified

staple crops (cassava, maize,
and sweet potato)

McEwan et al. [177] 2015 Narrative Sub-Saharan Africa Local seed systems
Carey et al. [178] March 2021 Narrative West Africa Frying quality

Mulongo et al. [179] June 2021 Narrative Sub-Sahara Africa Scaling-up orange-fleshed
sweet potato

Samuel et al. [180] March 2024 Systematic Global

Farmers’ adoption of
biofortified crops

(e.g., banana, cassava, rice
and sweet potato)

Neela and Fanta [181] June 2019 Narrative Sub-Sahara Africa

Nutritional content of
orange-fleshed sweet potato
(OFSP) and the approach to

managing vitamin A
deficiency



Agronomy 2025, 15, 766 23 of 32

Table A3. Articles dealing with sweet potatoes in Western Africa.

Year Number of Documents References

2024 * 6 Acheampong et al. [66]; Ejike et al. [116]; Kouassi et al. [62]; Lartey et al.
[88]; Sugri et al. [93]; Utoblo et al. [171]

2023 9
Adekambi et al. [162]; Agbede and Oyewumi [103]; Ahoudou et al. [51];
Etwire et al. [85]; Koffi et al. [61]; Kubuga et al. [87]; Mourtala et al. [49];
Olorunsogo et al. [146]; Sohindji et al. [53]

2022 12

Adekiya et al. [97]; Agbede and Oyewumi [101]; Agbede and Oyewumi
[102]; Agbede et al. [104]; Chinenye et al. [112]; Dania et al. [113]; Iheme
et al. [120]; Just et al. [121]; Mafulul et al. [127]; Shourove et al. [152]; Thiam
et al. [156]; Younge et al. [96]

2021 12

Adu-Kwarteng et al. [69]; Atuna et al. [74]; Dery et al. [163]; Ebem et al.
[114]; Hormenoo et al. [86]; Jean Maurel et al. [64]; Moyo et al. [170];
Ojimelukwe et al. [141]; Oloniyo et al. [145]; Oyeogbe et al. [149]; Oyinloye
et al. [150]; Ssali et al. [166]

2020 12

Adekambi et al. [50]; Adekambi et al. [67]; Adetola et al. [98]; Ayensu et al.
[76]; Baafi et al. [78]; Darko et al. [82]; Donkor et al. [83]; Feukam Nzudie
et al. [169]; Nayan et al. [129]; Sawadogo et al. [55]; Swanckaert et al. [94];
Tibiri et al. [59]

2019 12

Abidin et al. [167]; Adeyonu et al. [99]; Adom et al. [68]; Akomeah et al.
[70]; Alalade et al. [107]; Assefa et al. [168]; Ayensu et al. [75]; Carey et al.
[81]; Fereno et al. [158]; Law-Ogbomo and Ikpefan [125]; Law-Ogbomo and
Osaigbovo [126]; Tibiri et al. [58]

2018 3 Atuna et al. [73]; Lagerkvist et al. [122]; Nta et al. [133]

2017 6 Amagloh et al. [71]; Baafi et al. [77]; Glato et al. [164]; Ohizua et al. [140];
Sanoussi et al. [52]; Tortoe et al. [95]

2016 4 Bonsi et al. [79]; Okorie et al. [142]; Oshunsanya [148]; Yusuf et al. [154]

2015 9
Anyaegbunam et al. [111]; Ebeniro et al. [115]; Ekwe et al. [117]; Farayola
et al. [119]; Lawal et al. [124]; Peters [165]; Some et al. [57]; Sossah et al. [92];
Williams et al. [161]

2014 1 Nwokocha et al. [135]
2013 1 Oshunsanya [147]
2012 2 Ouédraogo et al. [54]; Nascimento [60]
2010 3 Agbede [100]; Dziedzoave et al. [84]; Morrison and Twumasi [89]

2009 5 Etela et al. [118]; Mahyao et al. [63]; Meludu [128]; Okpara et al. [143];
Okungbowa and Osagie [144]

2008 4 Aladesanwa and Adigun [106]; Odebode [136]; Odebode et al. [137]; Salau
et al. [151]

2007 6 Anikwe and Ubochi [108]; Larbi et al. [123]; Njoku et al. [130]; Ogbonna
et al. [139]; Quayson and Ayernor [91]; Tetchi et al. [65]

2006 1 Villordon et al. [172]
2004 1 Somé et al. [56]
2003 1 Rhodes [160]
2001 2 Ogbalu [138]; Nnam [132]
2000 2 Anuebunwa [110]; Nnam [131]
1998 3 Amenyenu et al. [72]; Bonsi et al. [80]; Otoo et al. [90]
1997 1 Kamara and Lahai [159]
1995 1 Anioke et al. [109]
1994 1 Alghali and Bockarie [157]

1992 4 Aiyelaagbe and Jolaoso [105]; Nwinyi [134]; Winter et al. [153]; Zuofa and
Tariah [155]

1991 1 Karim et al. [48]
* As of 31 May 2024.



Agronomy 2025, 15, 766 24 of 32

Table A4. Parts of sweet potatoes addressed in the selected documents.

Sweet Potato Part * Articles

Roots/Tubers

Abidin et al. [167]; Acheampong et al. [66]; Adekambi et al. [162]; Adekambi et al. [67];
Adekiya et al. [97]; Adetola et al. [98]; Adeyonu et al. [99]; Adom et al. [68]; Adu-Kwarteng et al.
[69]; Agbede [100]; Agbede and Oyewumi [101]; Agbede and Oyewumi [102]; Agbede et al.
[104]; Ahoudou et al. [51]; Alalade et al. [107]; Amenyenu et al. [72]; Anikwe and Ubochi [108];
Anyaegbunam et al. [111]; Atuna et al. [73]; Atuna et al. [74]; Ayensu et al. [75]; Baafi et al. [78];
Bonsi et al. [79]; Bonsi et al. [80]; Carey et al. [81]; Chinenye et al. [112]; Darko et al. [82]; Dery
et al. [163]; Dziedzoave et al. [84]; Ebem et al. [114]; Ebeniro et al. [115]; Ekwe et al. [117];
Etwire et al. [85]; Fereno et al. [158]; Feukam Nzudie et al. [169]; Iheme et al. [120]; Just et al.
[121]; Kamara and Lahai [159]; Koffi et al. [61]; Kouassi et al. [62]; Kubuga et al. [87]; Lagerkvist
et al. [122]; Larbi et al. [123]; Lartey et al. [88]; Lawal et al. [124]; Law-Ogbomo and Osaigbovo
[126]; Jean Maurel et al. [64]; Moyo et al. [170]; Nascimento [60]; Njoku et al. [130]; Nnam [131];
Nnam [132]; Nta et al. [133]; Nwinyi [134]; Nwokocha et al. [135]; Odebode [136]; Odebode
et al. [137]; Ohizua et al. [140]; Ojimelukwe et al. [141]; Okorie et al. [142]; Okpara et al. [143];
Okungbowa and Osagie [144]; Oloniyo et al. [145]; Oshunsanya [147]; Oshunsanya [148]; Otoo
et al. [90]; Ouédraogo et al. [54]; Peters [165]; Quayson and Ayernor [91]; Salau et al. [151];
Sanoussi et al. [52]; Shourove et al. [152]; Somé et al. [56]; Some et al. [57]; Ssali et al. [166];
Sugri et al. [93]; Swanckaert et al. [94]; Tetchi et al. [65]; Thiam et al. [156]; Tortoe et al. [95];
Williams et al. [161]; Younge et al. [96]; Yusuf et al. [154]

Leaves
Agbede and Oyewumi [102]; Amagloh et al. [71]; Amenyenu et al. [72]; Bonsi et al. [80]; Etela
et al. [118]; Larbi et al. [123]; Law-Ogbomo and Osaigbovo [126]; Mahyao et al. [63]; Morrison
and Twumasi [89]; Nwinyi [134]

Whole plant

Adekambi et al. [50]; Adekiya et al. [97]; Adom et al. [68]; Agbede [100]; Agbede and Oyewumi
[101]; Agbede and Oyewumi [102]; Agbede and Oyewumi [103]; Agbede et al. [104]; Ahoudou
et al. [51]; Aiyelaagbe and Jolaoso [105]; Akomeah et al. [70]; Aladesanwa and Adigun [106];
Alghali and Bockarie [157]; Amenyenu et al. [72]; Anikwe and Ubochi [108]; Anuebunwa [110];
Assefa et al. [168]; Atuna et al. [73]; Baafi et al. [78]; Bonsi et al. [80]; Carey et al. [81]; Darko
et al. [82]; Ebem et al. [114]; Ebeniro et al. [115]; Ejike et al. [116]; Etwire et al. [85]; Glato et al.
[164]; Hormenoo et al. [86]; Kamara and Lahai [159]; Karim et al. [48]; Kouassi et al. [62]; Larbi
et al. [123]; Lawal et al. [124]; Law-Ogbomo and Ikpefan [125]; Law-Ogbomo and Osaigbovo
[126]; Mourtala et al. [49]; Nayan et al. [129]; Njoku et al. [130]; Nwinyi [134]; Ogbalu [138];
Ogbonna et al. [139]; Ojimelukwe et al. [141]; Okorie et al. [142]; Okpara et al. [143]; Otoo et al.
[90]; Oyeogbe et al. [149]; Sanoussi et al. [52]; Sawadogo et al. [55]; Sohindji et al. [53]; Some
et al. [57]; Sossah et al. [92]; Sugri et al. [93]; Swanckaert et al. [94]; Tibiri et al. [58]; Tibiri et al.
[59]; Utoblo et al. [171]; Villordon et al. [172]; Zuofa and Tariah [155]

* Some documents deal with different parts of sweet potato.

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