Xanthosoma sagittifolium explained

Xanthosoma sagittifolium (Tannia) is a tropical flowering plant from the family Araceae. It produces an edible, starchy corm. X. sagittifolium is native to tropical America where it has been first cultivated. Around the 19th century, the plant spread to Southeast Asia and Africa and has been cultivated there ever since. X. sagittifolium is often confused with the related plant Colocasia esculenta (Taro), which looks very similar and is also used in a similar way. Both plants are often collectively named Cocoyam.[1]

Depending on the region, there are various common names for X. sagittifolium, including Tannia, Yautia, Malanga, (New) Cocoyam, the Arrowleaf Elephant's Ear, or American Taro.[2] Cultivars with purple stems or leaves are also variously called Blue Taro, Purplestem Taro, Purplestem Tannia, and Purple Elephant's Ear among others.[3] [4]

Tannia is among the world’s most important tuber crops and feeds 400 million people worldwide.[5] There are multiple varieties, the two most common being the red flesh and the white flesh variety.[6] They were artificially bred to improve pest and disease resistance, to shorten the time it takes to reach maturity and to improve the cooking quality.[5]

Uses

Cooking

Tannia is a versatile crop with both its corm and leaves suitable for human consumption. The corms can be categorized into smaller secondary corms and main corms. Secondary corms are primarily used in various culinary applications, in similar ways as potatoes. They can be boiled, fried, roasted, steamed, baked, or ground into flour (see chapter Flour). The leaves of the tannia plant find common culinary use as a leafy green, similar to spinach. In contrast, primary corms are typically designated for animal feed rather than human consumption because of the higher amount of oxalates.

In Bolivia, it is called walusa, in Colombia bore, in Costa Rica tiquizque or macal, in Cuba Spanish; Castilian: malanga, in Mexico Spanish; Castilian: mafafa, in Nicaragua Spanish; Castilian: quequisque, in Panama Spanish; Castilian: otoe, in Dominican cuisine is called yautia, yautia morada, and yautia coco and Spanish; Castilian: ocumo in Venezuela. In Brazil, the leaves are sold as Portuguese: taioba. The tuber (called Spanish; Castilian: nampi or Spanish; Castilian: malanga) is also used in the cuisine of these countries. The plant is often interplanted within reforestation areas to control weeds and provide shade during the early stages of growth.

In Puerto Rican cuisine and Dominican cuisine, the plant and its corm are called yautía. In Dominican Republic as well as in Puerto Rican pasteles en hoja, yautía is ground with squash, potato, green bananas and plantains into a dough-like fluid paste containing pork and ham, and boiled in a banana leaf or paper wrapper. The yautía corm is used in stews, soups, or simply served boiled much like a potato. It is used in local dishes such as guanime, alcapurrias, sancocho, and mondongo. In alcapurrias, it is also ground with green bananas and made into fried croquettes containing picadillo or seafood. Yautía majada is also prepared and consumed when mashed in some instances. Yautía puree is usually served with fish or shellfish cooked in coconut milk.

In Suriname and the Netherlands, the plant is called tayer. The shredded root is baked with chicken, fruit juices, salted meat, and spices in the popular Surinamese dish, pom. Eaten over rice or on bread, pom is commonly eaten in Suriname at family gatherings and on special occasions, and is also popular throughout the Netherlands. In Surinamese cuisine the leaves are also often baked with a Maggi-cube (chicken boullion cube) and eaten alongside rice and chicken or salted beef.

Flour

Flour can be made by slicing the rhizome and then drying it. Afterwards, it can be finely grinded. The yield of the starch is about 15%.[7] A big problem of tannia is the low storability because of the high moisture content of the corms and cormels.[8] Processing the tubers into flour could increase the storability of the crop and could increase the added value. Local farmers then would be able to sell their crop for a higher price, which could then help the local community.[8] Especially the white fleshed variety provides flour that has qualities that are great for making bread, since the resulting paste is not as cohesive and can therefore be used for the preparation of different foods.[6] Flour could also easily be used in meat and milk products.[7] A disadvantage of the flour is the (especially in comparison with flour made from cassava) lower starch content and it therefore would be best to only make flour as a byproduct of other processes.[5] It could also be made from cormels that do not provide the necessary quality for cooking.

Chicken feed

Studies have shown that it’s possible to replace up to 45% of the maize grain in chicken feed with tannia corn meal (TCM). This could be useful for farmers since chicken feed which consists of maize grains is very expensive - especially in poorer countries. At the beginning of their growing phase, chickens fed with TCM consume significantly more because TCM reduces the nutrient uptake and weight gain. Later in the growing stage, this effect diminishes and in the end, there is no difference in the weight of chickens fed with TCM in comparison to chickens fed entirely with maize grains.[9]

Additional uses

Tannia is used by some populations as a medicine against tarantula, scorpion and snake bites.[5] Studies with rats have shown that tannia leaves could protect from cardiovascular diseases[10] and bowel cancer. Other benefits include a reduced weight gain, reduced liver fat, increased fecal mass and higher concentration of short chain fatty acids and bile salt.[10] It has also shown a probiotic effect.[11] Another study has shown that tannia can stop the cell cycle and force apoptosis in a cancer cell. Tannia also has been traditionally used to treat osteoporosis because of the high content of free calcium analyses. Studies have shown that the usage of tannia indeed is a feasible option for treatment for poorer communities without access to proper medication.[12]

Cocoa trees can grow in direct sunlight, but in some climates, the intense light in the afternoon can damage the leaves.Tannia has many leaves which makes it a good candidate for a cover crop that can protect the cocoa plant from direct sunlight. Another advantage of Tannia is that it can grow in many different climates and therefore would be suitable for many different countries.[5]

Tannia could also be used to make food preservatives (lactic acid), energy bars,[11] chips and crisps, additives in beverages, sauce thickeners, purees, and sauces.[5] Lastly, there is the possibility to use tannia to make ethanol for biofuel because of the high starch content and the high yield.

Cultivation

Climate requirements

Although its exact native range is uncertain, the plant is now widely cultivated in the American tropics. This cultivation is not only for ornamental purposes but also, both privately and commercially, for its edible parts.[13] Xanthosoma sagittifolium is an adaptable plant that grows optimally in warm and humid conditions and temperatures above 25 degrees Celsius.[14] At lower temperatures and in arid climates, the development of the plant is hindered. For proper development, the plant needs rainfall evenly distributed throughout the year.[15]

It is noteworthy that tannia is one of the most shade-tolerant plants, which allows successful cultivation in traditional Agroforestry systems and facilitates intercropping with perennial crops such as bananas, cocoas or oil palms.[16]

The optimal soil conditions for the plant to thrive are well-drained, loamy soils with a pH between 5.5 and 6.5. However, Tannia can grow in various soil types, with the exception of hard clay or pure sand, but generally prefers soils high in organic matter. In general, the plant's adaptability allows it to flourish in a wide range of soils and habitats.

Planting

The best time for planting depends on the local climatic conditions of the growing region. However, it is suggested to do the planting during the rainy season and when the soil is sufficiently moist.

Small parts of the corms or cormels are used for planting. These propagating materials are typically planted at a depth of 7–10 cm, ideally with the growth bud pointing downward. Planting is done in rows half a meter to one meter apart to allow the corms and cormels to develop well and to facilitate the harvest. More dense planting leads to higher yields per field and less weeding, more space results in a higher yield per plant but more weeding work. Crop Management is done manually using simple tools such as digging sticks or bush knives.

Harvesting

The typical tannia plant has a 9 to 11 months growing cycle.[17] During this time, it produces a large stem called a corm, which is surrounded by smaller edible cormels about the size of potatoes. Harvesting these edible aroids typically occurs when the leaves start to turn yellow. During the growth cycle, a plant typically produces approximately 40-50 leaves, which are usually harvested within a 40-50 day period.

Mature cormels can be harvested continuously over an extended period of time, often exceeding 500 days, while the primary mother plant remains in the ground to produce a new crop.

Harvesting is commonly carried out manually or with semi-mechanized equipment. After harvesting, the corms are cured to slow down the rate of physiological and pathological decay of the tuber, which would result in loss of quality. Further losses may occur due to the short shelf life of the tubers. Also storage at ambient temperatures poses a challenge.

Nutritional Value

Tannia is an important source of starch in many African countries such as Ethiopia. Its tubers contain approximately 85% carbohydrates in dry matter.[18] Furthermore, the protein content amounts to 10% - a benefit for the resource-poor farmers by whom Tannia is mainly consumed. The plant is also rich in vitamin A and vitamin C and a good source of potassium, calcium and other minerals.[19]

However, the presence of the so-called calcium oxalate must be considered, a compound known to irritate mucous membranes, resulting in crystalline deposits commonly referred to as crystal sand. Consumption of these corms can lead to a scratchy sensation in the mouth and throat. To mitigate this effect, the corms need to be boiled before consumption, as this process allows the substances to dissolve in the cooking water, making the corms safe to eat.

Diseases

Root Rot Disease is the most important disease in Tannia. The oomycete Pythium myriotylum is probably the main causal agent of the Root Rot Disease. Other organisms that could be involved are Phytopthora ssp., Fusarium ssp., Penicillium ssp., Botrydioplodia ssp., Erwinia ssp. and Pseudomonas ssp.[20] [21] Symptoms are stunted growth, wilting, chlorotic and withered leaves and a poor root system. The disease leads to low yields or even complete crop failure.[22] [23] The disease spreads through soil and planting material. The pathogens can persist for a long time in the soil, often forcing farmers to give up planting Tannia in infected fields for at least five years. Wetland, floodings and poorly drained soils are associated with the appearance of Root Rot Disease. As long as the field is not yet infected, the best method to control the disease is to use disease-free planting material. Further cultural control methods are general strengthening of plant health, drainage, crop rotation and planting on ridges. There are cultivars that are less susceptible to root rot, but none of them are resistant. Various fungicides are effective in case of infection.

Dasheen Mosaic Potyvirus is the most important virus that infects Tannia and other aroids. Symptoms are chlorotic mosaic patterns along the veins and stunting. The Dasheen Mosaic Virus is not lethal but can reduce the yield significantly. The virus is transmitted by aphids. It can be spread vegetativly by planting material and mechanically by sap transmission while using tools. It is therefore important to use virus-free plant material and to work hygienically. The control of the vector aphids would be effectiv, but is difficult.[24] [25]

Taro Leaf Blight, caused by Phytophthora colocasiae, is not a problem in Tannia. Some varietys of Tannia even seem to be resistant against it. On contrast, in Taro (Colocasia esculenta), a related and similar-looking crop plant, this is a major disease problem.

External links

Notes and References

  1. Book: Onwueme . I. C. . Tropical root and tuber crops: production, perspectives and future prospects . Charles . W. B. . 1994 . FAO . FAO . 978-92-5-103461-3 . FAO plant production and protection paper . Rome.
  2. Book: Lim, T. K.. 10.1007/978-94-017-9511-1_15. Xanthosoma sagittifolium. Edible Medicinal and non Medicinal Plants. 498–509. 2015. 978-94-017-9510-4.
  3. Web site: Xanthosoma violaceum. Tropical Britain. 22 January 2017. https://web.archive.org/web/20170202085443/http://www.tropicalbritain.co.uk/aroids/xanthosoma/xanthosoma-violaceum/xanthosoma-violaceum.html. 2 February 2017. dead.
  4. Web site: Xanthosoma violaceum from Tropical Britain - Purple Elephant's Ears. Tropical Britain. 10 May 2022.
  5. Boakye . Abena A. . Wireko-Manu . Faustina Dufie . Oduro . Ibok . Ellis . William O. . Gudjónsdóttir . María . Chronakis . Ioannis S. . June 2018 . Utilizing cocoyam (Xanthosoma sagittifolium) for food and nutrition security: A review . Food Science & Nutrition . en . 6 . 4 . 703–713 . 10.1002/fsn3.602 . free . 2048-7177 . 6021709 . 29983932.
  6. Sefa-Dedeh . Samuel . Kofi-Agyir Sackey . Emmanuel . 2002-12-01 . Starch structure and some properties of cocoyam (Xanthosoma sagittifolium and Colocasia esculenta) starch and raphides . Food Chemistry . 79 . 4 . 435–444 . 10.1016/S0308-8146(02)00194-2 . 0308-8146.
  7. Morais . A. F. . Canapá . L. B. S. . Silveira . M. F. A. . Vera . R. . 2020-09-01 . https://sea.ufr.edu.br/index.php?journal=SEA&page=article&op=view&path[=1201 Production and characterization of tannia rhizome flour ]. Scientific Electronic Archives . 13 . 9 . 67 . 10.36560/13920201201 . 2316-9281. free .
  8. Pérez . Elevina . Schultz . Forrest S. . de Delahaye . Emperatríz Pacheco . 2005-05-06 . Characterization of some properties of starches isolated from Xanthosoma sagittifolium (tannia) and Colocassia esculenta (taro) . Carbohydrate Polymers . 60 . 2 . 139–145 . 10.1016/j.carbpol.2004.11.033 . 0144-8617.
  9. Edmew . Tewabe . Muleta . Eyerus . Worku . Zemene . 2023-12-31 . Effects of different graded levels of tannia (Xanthosoma sagittifolium) on growth performance of broiler chicken . Cogent Food & Agriculture . en . 9 . 1 . 10.1080/23311932.2023.2252553 . 2331-1932. free . 2023CogFA...952553E .
  10. de Almeida Jackix . Elisa . Monteiro . Elisa Bernardes . Raposo . Helena Fonseca . Amaya-Farfán . Jaime . 2013-05-01 . Cholesterol reducing and bile-acid binding properties of taioba (Xanthosoma sagittifolium) leaf in rats fed a high-fat diet . Food Research International . 51 . 2 . 886–891 . 10.1016/j.foodres.2013.02.017 . 0963-9969. free .
  11. Book: Jehannara Calle . Nicola Gasparre . Yaiza Benavent-Gil . Cristina M. Rosell . Chapter Eight – Aroids as underexplored tubers with potential health benefits . 2021 . Advances in Food and Nutrition Research . 97 . 319–359 . Academic Press . en-US . 10.1016/bs.afnr.2021.02.018. 34311903 . 978-0-12-824580-4 . 234955983 .
  12. de Oliveira . Gisele Lopes . Holanda Cavalcanti Andrade . Laise de . Morais de Oliveira . Antonio Fernando . 2012 . Xanthosoma sagittifolium and Laportea aestuans: Species used to prevent osteoporosis in Brazilian traditional medicine . Pharmaceutical Biology . en . 50 . 7 . 930–932 . 10.3109/13880209.2011.637054 . free . 22468879 . 1388-0209.
  13. Web site: Xanthosoma sagittifolium - Plant Finder . 2024-05-22 . www.missouribotanicalgarden.org.
  14. Siqueira, M., Nascimento, W., Pedrosa, M., & Veasey, E. (2023). Agronomic characteristics (varieties or landraces) and potential of Xanthosoma sagittifolium as food and starch source. In M. P. Cereda & O. F. Vilpoux (Eds.), Varieties and Landraces (pp. 261–272). Academic Press. https://doi.org/10.1016/B978-0-323-90057-7.00010-3
  15. Jagtap, K. B., & Vilas, C. A. (2017). Tannia. In M. K. Rana (Ed.), Vegetable Crop Science (1st ed.) (pp. 79–86). CRC Press.
  16. Manner, H. I. (2011). Farm and Forestry Production and Marketing Profile for Tannia. In C. R. Elevitch (Ed.), Speciality Crops for Pacific Island Agroforestry.
  17. Opara, L. U. (2003). Edible Aroids: Post-Harvest Operation. Massey University, Food and Agriculture Organization of the United Nations.
  18. Wada, E., Feyissa, T. & Tesfaye, K. (2019). Proximate, mineral and antinutrient contents of Cocoyam (Xanthosoma sagittifolium (L.) Schott) from Ethiopia. International journal of food science, 2019, 1–7. https://doi.org/10.1155/2019/8965476
  19. Siqueira, M. V. B. M., Nascimento, W. F. D., Pedrosa, M. W. & Veasey, E. A. (2023). Agronomic characteristics (varieties or landraces) and potential of Xanthosoma sagittifolium as food and starch source. In Elsevier eBooks (S. 261–272). https://doi.org/10.1016/b978-0-323-90057-7.00010-3
  20. Pacumbaba . R. P. . Wutoh . J. G. . Eyango . Sama Anne . Tambong . J. T. . Nyochembeng . L. M. . 1992 . Isolation and Pathogenicity of Rhizosphere Fungi of Cocoyam in Relation to Cocoyam Root Rot Disease . Journal of Phytopathology . en . 135 . 4 . 265–273 . 10.1111/j.1439-0434.1992.tb04312.x . 0931-1785.
  21. Book: Reddy . P. Parvatha . Plant protection in tropical root and tuber crops . Parvatha Reddy . P. . 2015 . Springer . 978-81-322-2388-7 . New Delhi Heidelberg New York, NY Dordrecht London.
  22. Wutoh . J.G. . Tambong . J.T. . Meboka . M.M. . Nzietchueng . S. . 1994 . Field Evaluation of Cocoyam (Xanthosoma Sagittifolium (L) SCHOTT) For Tolerance to the Root Rot Disease caused by Pythium Myriotylum . Acta Horticulturae . 380 . 462–466 . 10.17660/actahortic.1994.380.71 . 0567-7572.
  23. Onyeka . Joseph . 2014 . Status of Cocoyam (Colocasia esculenta and Xanthosoma spp) in West and Central Africa: Production, Household Importance and the Threat from Leaf Blight. Lima (Peru). CGIAR Research Program on Roots, Tubers and Bananas (RTB) . CGIAR Research Program on Roots, Tubers and Bananas (RTB).
  24. REYES . G. . RÖNNBERG-WÄSTLJUNG . A. C. . NYMAN . M. . 2006 . COMPARISON OF FIELD PERFORMANCE BETWEEN DASHEEN MOSAIC VIRUS-FREE AND VIRUS-INFECTED IN VITRO PLANTS OF COCOYAM (XANTHOSOMA SPP.) IN NICARAGUA . Experimental Agriculture . 42 . 3 . 301–310 . 10.1017/s0014479706003590 . 85098812 . 0014-4797.
  25. Nelson . Scot C. . 2008 . Dasheen Mosaic of Edible and Ornamental Aroids . Honolulu (HI): University of Hawaii . 10125/12392 . en-US.