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Vigna subterranea (common names: Bambara groundnut, Bambara nut, Bambara bean, Congo goober, earth pea, ground-bean, or hog-peanut ) is a member of the family Fabaceae. Its name is derived from the Bambara tribe, who currently lives in Mali. The plant originated in West Africa. As a food and source of income, the Bambara groundnut is considered to be the third most important leguminous crop in those African countries where it is grown, after peanut and cowpea. The crop is mainly cultivated, sold and processed by women, and is, thus, particularly valuable for female subsistence farmers.

Bambara groundnut represents the third most important grain legume in semi-arid Africa. It is resistant to high temperatures and is suitable for marginal soils where other leguminous crops cannot be grown. It is a low-impact crop. The entire plant is known for soil improvement because of nitrogen fixation.

Vigna subterranea ripens its pods underground, much like the peanut (also called a groundnut). They can be eaten fresh or boiled after drying, and can be ground either fresh or dry to make puddings.

Origins and regions of cultivation
The origin of the Bambara groundnut is West Africa and the region of cultivation is Sub-Saharan Africa's warm tropics. Bambara nut grows well anywhere groundnut (peanut) grows, and so is vastly present from Kwara state, throughout the northern parts of Nigeria and Northern Ghana.

Growth, development, physiology
Bambara groundnut is a herbaceous, intermediate, annual plant, with creeping stems at ground level. It is a small legume plant that grows to a height of 0.25–0.37m with compound leaves of three leaflets having stipules about 3 mm long. The flowers have a tube calyx about 1 mm long and 5 lobes about 1 mm long as well as a whitish yellow corolla, 4–7 mm long. The fruit is an indehiscent pod almost globose about 2.5 cm in diameter. The plant generally looks like bunched leaves arising from branched stems, which form a crown on the soil surface.

Bambara is considered as a fast-growing crop. The growth cycle is between (min-max) 90–170 days and under optimal conditions the cycle is about 120–150 days to pod maturity. Flowers appear 40–60 days after planting. 30 days after pollination the pod reaches maturity and during another 55 days the seeds fully develop. Every 30 days they are produced again.

Generative reproduction is for the Bambara groundnut autogamous (self-fertilization) and cleistogamous (self-pollinating). After self-fertilization, pale yellow flowers are borne on the freely growing branching stems; these stems then grow downwards into the soil, taking the developing seed within the pods, which makes breeding and development of new cultivars for the traits of interest difficult. The seeds will form pods encasing seeds just below the soil. The pods are round, wrinkled and each contains one or two seeds that are round, smooth and very hard when dried.The seeds may be cream colored, brown, red, mottled or black eyed and their size is about 8.5–15 mm × 6.5–10 mm × 5.5–9 mm.

Several factors are essential for promoting cross-pollination in Bambara and these include a proper nursery habitat, short day lengths (<12h), an average temperature of 26°C, which is necessary for optimum flowering and pod formation and a relative humidity of 90%. The strict photoperiod requirement of Bambara also limits its productivity in countries further away from the equator. In some accessions, long days (>12h) negatively affect pod-setting, resulting in crop failure.

The genus Vigna, which includes about 80 species, is found throughout the tropics. There are considerable morphological differences between wild and domesticated types of Bambara groundnuts. Long runners are produced by wild Bambara groundnut, and the seeds are smaller (9–11 mm long) and more uniform in size. The pods are thin and do not wrinkle when drying. Domesticated versions are more compact, have fleshy pods that wrinkle as they dry, with longer, less slender, and more erect petioles, and larger seeds (11–15 mm long). Wild and domesticated types are sometimes distinguished as ''var. spontanea (Harms) Hepper (wild) and var. subterranea'' (cultivated).

Biological Nitrogen Fixation
Like many other legumes, Bambara groundnut fixes atmospheric nitrogen through the process of biological nitrogen fixation. Its potential to be used as an alternative to chemical fertilizer in agriculture has been investigated for many years. The process is also very important to improve soil fertility and to supply other non-leguminous crops with the nitrogen left in the soil after the legume is harvested. Bambara groundnut can fix 32 to 81 kg N /ha.

Soil requirements
Optimal soils for Bambara groundnut production are sandy soils to prevent waterlogging. Well-drained soils make the harvest easier and prevent rotting of the pods. Stony areas should however be avoided to prevent damage of the pods.

Optimal soil depth is between 50 and 100 cm, with a light soil texture. Soil fertility should be low and soil pH is best suited between 5 and 6.5 and should not be lower than 4.3 or higher than 7. Bambara groundnut is tolerant to salinity, but high sodium chloride concentration in the soil will result in yield losses.

Climate requirements
The production is best suited between a latitude of 20°- 30°, i.e. the tropical wet and dry (Aw) and the subtropical dry summer (Cs) climate zones. Optimal temperature is between 19 °C and 30 °C. Temperatures below 16 °C and above 38 °C are not suited for the production of Bambara groundnut.

The Bambara groundnut is very drought-resistant. The minimal annual rainfall requirement is about 300 mm and optimal annual rainfall is between 750 mm and 1400 mm and should not exceed 3000 mm. Bambara groundnut can tolerate heavy rainfall, but it will result in yield losses if they happen at harvest.

Seedbed requirements and sowing
Before sowing, the seeds can be treated with pesticides to prevent insect and fungal attack, and being eaten by bush fowl (Numida meleagris). Priming the seeds with water by soaking them overnight and then drying them before sowing improves seedling emergence, vigour and yield.

Sowing is usually performed manually by peasant farmers in tropical Africa, but it can also be done mechanically on industrial farms using modified soya bean planters. Manual sowing is generally done using a hoe or a cutlass to open the soil. One seed is placed in each hole which are then closed.

Seedbed type doesn’t seem to affect yield or biomass production of Bambara groundnut. The crop can thus be planted on flat terrain, although it is also planted in ridges. Studies show that increased sowing density has a positive effect on production calculated on a per-area basis, but has a negative effect on per-plant yield. It is assumed that at higher sowing densities, increased competition between plants is the cause of lower pod and seed number per plant.

Cropping system and fertilization
The cropping system is semi-permanent and the Bambara groundnut can be cultivated as single crop or as intercrop. Best suited intercrops are sorghum, millet, maize, peanut, yams and cassava. Bambara groundnut is mainly cultivated as intercrop, however the planting density varies between 6 and 29 plants per square meter. For woodland savannas of Côte d'Ivoire, the highest yield is attainable with a plant density of 25 plants per square meter. Despite its suitability for intercropping systems due to its ability to fix atmospheric nitrogen, a non-negligible proportion of farmers grow the Bambara groundnut in monoculture and report that its performance is better as a single crop. Cultivation is mainly performed manually and is comparable to the production of peanut.

The crop needs less mineral elements than groundnuts (Arachis hypogaea L.) and, therefore, has higher yields on low-fertility soils. Nevertheless, fertilization, especially with phosphate, can still improve the yield and growth development of the Bambara groudnut. Depending on the soil and the country, the application of superphosphate ranging from 60 to 250 kg/ha has been shown to significantly improve the yield of this crop. A study in Cameroon also managed to use arbuscular mycorrhizal fungi to improve the crop performance by biological fertilization. Since nitrogen is provided by the symbiotic Rhizobium bacteria, additional nitrogen fertilization is usually not necessary. High nitrogen levels in the soil even result in fewer pods and lower seed production. However, nitrogen fertilization can be beneficial in some cases, notably when assimilation is poor and at early growth stages.

Harvest and postharvest treatment
The Bambara bean typically takes about 130-150 days to mature, but early or late harvests only marginally reduce the yield. The pods, which grow belowground, are harvested manually by pulling out the whole crop and picking the pods by hand. Then, they are usually dried in the sun for some days. Post-harvest losses are reported to be on a low level. However, insect pests can cause damage to stored grains, most importantly Bruchids.

Interactions: Pests, diseases, symbionts
It is widely regarded as a pest and disease resistant crop. However, there is a lack of evidence to support this claim, with reports of fungal attacks by Rhizoctonia solani in Southern Thailand, and Cercospora canescens and Colletotrichum capsici in Nigeria, causing brown blotch disease. The crop is also susceptible to attack by cowpea weevil (Callosobruchus maculatus).

Importance
The annual production of Bambara groundnut is estimated to be 0.2 million tonnes from an area of 0.25 million hectares worldwide. Sub-Saharan Africa (SSA) is the largest producer of Bambara groundnut, while a small quantity is produced in Southeast Asia (e.g., Thailand and Indonesia), the United States of America (USA), and Australia. Additionally, the crop is cultivated in Brazil, where it was putatively introduced in the 1600s with the slave trade. West Africa is the main Bambara groundnut production region in SSA, where Burkina Faso, Niger, and Cameroon are the leading producers, contributing to 74% of global production. However, it was reported by Ghanaean farmers to contribute neither to a large part of the subsistence food nor of the income.

Worldwide production and yield
World production of Vigna subterranea increased from 29,800 tonnes in 1972 to 79,155 tonnes in 2015.

The top six Bambara groundnut producing countries in Africa in 2018 include Burkina Faso, Niger, Cameroon, Mali, Togo and the Democratic Republic of the Congo with a total production of 0.06, 0.05, 0.04, 0.03, 0.02, and 0.01 million tonnes, respectively.

The yield level of Bambara groundnut in Africa varies from 0.6−1 t ha-1, depending on variety and production conditions. However, unshelled mean yields of up to 3 t ha-1 were reported when cultivating some landraces in the transition agro-ecological zone in Nigeria. A low mean yield of 0.85 t ha-1 was reported in Ghana under good management practices close to yield levels of other legumes such as cowpeas (0.80 t ha-1) and pigeon peas (0.78 t ha-1).

Nutrition
This nutrient-dense legume is sometimes termed a “complete food” due to its balanced macronutrient composition. It is considered to be a neglected and underutilized food source in Benin. The brown hull showed the highest concentrations of rutin and myricetin among flavonoids, while the red hull resulted in having with the highest concentrations of chlorogenic and ellagic acid among tannin compounds.

Macronutrient content
Bambara groundnut has nutritive value ranging between 57.9% to 64% carbohydrate and 24.0% to 25.5% protein content. In comparison, soybean (Glycine max) and chickpea (Cicer ariteneum) have 27% and 61% of carbohydrates.

Anti-nutritional factors
The presence of anti-nutritional factors (ANFs) in the Vigna subterranea can reduce protein digestibility, affecting bioavailability of amino acids by up to 50%, as well as lowering digestibility and bioavailability of other nutrients. ANFs include enzyme inhibitors, flatulence factors, tannins, phytic acid and saponins. ANFs can be removed or lowered by a variety of treatments:


 * 1) Cooking and thermal treatment of pulse seeds.


 * 1) Soaking followed by cooking of Bambara groundnut seeds.


 * 1) Processing methods such as soaking, germination, fermentation, and treatment with phytase have been successful in reducing phytic acid content of chickpeas, sorghum and millet.


 * 1) Applications of pressure, heat, infrared radiation, dry extrusion and chemicals such as cysteine have been shown to reduce trypsin inhibitor activity in whole soybean.

Culinary use
The seeds are used for food, beverages because of their high protein content and for digestive system applications. In West Africa, the nuts are eaten as a snack, roasted and salted, processed into cake, or as a meal, boiled similar to other beans.

The Bambara groundnut needs to be cooked for a relatively long time, which means that more fuel is needed than for cooking other legumes. The cooking time of fresh beans is 45-60 minutes, dry beans may even take 3-4 hours. This presents an obstacle to a more widespread use of this crop. Moreover, if the bean is not cooked enough, it can cause bloating of the stomach, constipation and flatulence.

Traditional culinary use of Bambara groundnut in Nigeria
In South Eastern Nigeria, particularly in Enugu, the dried Bambara beans are ground into a fine powder, then mixed with palm oil, water and pumpkin leaves and then poured into banana leaf wraps or one-litre cellophane bags before being boiled into a pudding to make Okpa, a common breakfast food. During the rainy season in many parts of central Nigeria, the fresh Bambara beans are cooked with their shells still on them, then eaten as a snack.

Potential use in probiotic beverage
Bambara groundnut milk can be fermented with lactic acid bacteria to make a probiotic beverage that not only increase the economic value of the nutritious legume but also help in addressing malnutrition.

Use as livestock feed
The Bambara groundnut plays an important role in the diet and culture of populations. The leaves, rich in phosphorus, are used for livestock feed. Seeds are given to pigs and poultry while leafy stems are used as livestock fodder.

Potential medicinal use
The Bambara groundnut is very interesting for potential medical use due to the Flavonoid content, which can be as high as 24.46 mg/g (concentration of rutin in brown hulls). flavonoids have been reported to possess many useful properties, including anti-inflammatory activity, oestrogenic activity, enzyme inhibition, antimicrobial activity antiallergic activity, antioxidant activity, vascular activity and cytotoxic antitumor activity. It is reported an antimicrobial activity against Klebsiella pneumoniae, Pseudomonas aeruginosa, Staphylococcus aureus, Escherichia coli, Bacillus cereus, Candida albicans (yeast) and Aspergillus niger (mold).

Uses in traditional African medicine
The seeds and leaves of Bambara groundnut have been used for a long time in traditional medicine. Leaf preparations are used in Senegal to treat abscesses and infected wounds. The juice extracted from the leaf is applied to the eyes to treat epilepsy and the roots are sometimes used as an aphrodisiac. Crushed seeds, mixed with water, are administered to treat cataracts. The Ibo of Nigeria use the plant to treat venereal diseases. In Cameroon, Bambara groundnuts are used to fight amoebic dysentery, sore throat, headaches, stomach pain, joint pain and bone decalcification. It helps in digestion through its laxative properties. It stimulates milk production in breastfeeding women and is given to women who have just given birth to heal their wounds. Bambara groundnut seeds also contain kaempferol, an antioxidant polyphenol, which reduces the risk of many chronic diseases such as cancer. These uses come from the cultural medicine, not evidence-based medicine.

Breeding aims
There are a lot of genetic resources available for breeding since around 6145 germplasms of the Bambara groundnut have been collected and are stored ex situ (Khan et al. 2021). The primary goal of Bambara improvement programs is to focus on seed yield and nutritional quality traits. There is a notable gap between the potential yield of 4 t/ha and the average yield of 0.85 t/ha reported for African countries. Thus, breeding should aim at improving the yield. Results of studies exhibited high protein content among the test genotypes. Similarly, high levels of essential fatty acids, thiamine, ribovin, and vitamin K were recorded. Moreover, scientists examined the chemical properties of starches in Bambara groundnut. The results revealed that seed source/origin and crop management practices affected chemical composition. Food fortification, the use of artificial supplements, and food imports are among the strategies used to overcome the problem of malnutrition in Africa. The adoption of traditional plant breeding methods to enhance nutritional benefits of orphan food crops such as Bambara groundnut is an economic and affordable strategy to decrease malnutrition in Africa.

The form and colour of BGN were all important factors to optimize the best extraction yield of phytochemicals. Overall, the hulls of the BGN were the optimum source of flavonoids and tannins: the brown and red hulls had the highest concentration of flavonoids compared to whole and dehulled, with the highest flavonoid concentration being rutin at 24.46 mg g−1 found in brown hulls and myricetin at 1.80 mg g−1 found in red hulls. Lastly, formulating products with higher concentration of BGN hulls could potentially result in a product with higher phytochemical content.