Nawal Taaime, Sifeddine Rafik, Khalil El Mejahed, A. Oukarroum, R. Choukr-allah, R. Bouabid, M. El Gharous
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For this reason, we conducted a systematic review of agronomic management practices in 148 field experiments conducted worldwide from 2000 to 2022. The collected data from the literature were analyzed and presented by location to determine high-performing genotypes, optimal planting dates, and other adequate cropping practices affecting quinoa performance and yield. Results showed that quinoa could be successfully cultivated in the new farming areas. Quinoa yields were higher than those reported in its place of origin, ranging from 108 kg ha-1, obtained by KU-2 in Washington State, to 9667 kg ha-1, obtained by Longli in China. Although quinoa is considered a crop with low input requirements, positive grain yield response was observed following increasing fertilization rates. Quinoa needs 2 to 4.6 kg of nitrogen to produce 1q of grain yield. In terms of phosphorus and potassium, quinoa needs 3.7 kg P2O5 and 4.3 kg K2O to produce 1 ton of total biomass. Quinoa has low water requirements (300-400 mm). However, a positive response was recorded with water quantities up to 866 mm. During our investigation, weed control in quinoa crop is still undeveloped and usually done manually. Research addressing this issue can increase quinoa yields and decrease the production cost. Downey mildew and birds’ attack are the major phytosanitary problems affecting quinoa grain yield. Other pests such as miners and aphids can also affect the health of quinoa, but their injury is not a serious problem. After the harvest, saponins found in the out layer of the seed can be removed through washing and mechanical pearling process, but the latter technic was found to be efficient and cost effective to reduce the saponin content. 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The outstanding nutritional status of quinoa, with its high content of proteins, vitamins, and minerals, makes it a promising crop able to combat hunger and malnutrition in different countries in the 21st century. Quinoa cultivation has expanded from South America to Africa, Europe, Asia, and North America. Reviewing quinoa cropping practices will provide farmers with adequate recommendations for improving the agronomic and environmental sustainability of quinoa cultivation worldwide. For this reason, we conducted a systematic review of agronomic management practices in 148 field experiments conducted worldwide from 2000 to 2022. The collected data from the literature were analyzed and presented by location to determine high-performing genotypes, optimal planting dates, and other adequate cropping practices affecting quinoa performance and yield. Results showed that quinoa could be successfully cultivated in the new farming areas. Quinoa yields were higher than those reported in its place of origin, ranging from 108 kg ha-1, obtained by KU-2 in Washington State, to 9667 kg ha-1, obtained by Longli in China. Although quinoa is considered a crop with low input requirements, positive grain yield response was observed following increasing fertilization rates. Quinoa needs 2 to 4.6 kg of nitrogen to produce 1q of grain yield. In terms of phosphorus and potassium, quinoa needs 3.7 kg P2O5 and 4.3 kg K2O to produce 1 ton of total biomass. Quinoa has low water requirements (300-400 mm). However, a positive response was recorded with water quantities up to 866 mm. During our investigation, weed control in quinoa crop is still undeveloped and usually done manually. Research addressing this issue can increase quinoa yields and decrease the production cost. Downey mildew and birds’ attack are the major phytosanitary problems affecting quinoa grain yield. 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引用次数: 2
摘要
藜麦(野生藜麦)是一种耐旱耐盐作物,起源于7000多年前的安第斯山脉。它适应于不同的农业生态区,从海平面到海拔4000米都可以种植。藜麦的蛋白质、维生素和矿物质含量高,具有突出的营养地位,使其成为21世纪各国抗击饥饿和营养不良的有前途的作物。藜麦种植已经从南美扩展到非洲、欧洲、亚洲和北美。审查藜麦种植方法将为农民提供适当的建议,以改善全球藜麦种植的农艺和环境可持续性。因此,我们对2000年至2022年在全球范围内进行的148项田间试验的农艺管理实践进行了系统回顾。对从文献中收集的数据进行分析,并按地点进行展示,以确定高效基因型、最佳种植日期以及其他影响藜麦性能和产量的适当种植方法。结果表明,藜麦可在新农区成功种植。藜麦产量高于其原产地报告,从华盛顿州KU-2获得的108 kg ha-1到中国龙利获得的9667 kg ha-1。虽然藜麦被认为是一种投入需求低的作物,但在增加施肥量后,观察到籽粒产量的正响应。藜麦需要2到4.6公斤的氮才能产生1q的粮食产量。在磷和钾方面,藜麦需要3.7 kg P2O5和4.3 kg K2O来产生1吨总生物量。藜麦需水量低(300-400毫米)。然而,当水量达到866毫米时,记录了积极的反应。在我们的调查中,藜麦作物的杂草控制仍然不发达,通常是人工控制。解决这一问题的研究可以提高藜麦产量并降低生产成本。唐尼霉病和鸟类侵染是影响藜麦籽粒产量的主要植物检疫问题。其他害虫,如矿工和蚜虫也会影响藜麦的健康,但它们的伤害不是一个严重的问题。在收获后,可以通过清洗和机械珍珠工艺去除种子外层的皂苷,但发现后一种技术可以有效地降低皂苷的含量。我们的研究结果为藜麦作物在世界范围内适当的农艺实践提供了第一个推荐基础。
Worldwide development of agronomic management practices for quinoa cultivation: a systematic review
Quinoa (Chenopodium quinoa Wild.) is a drought and salinity-tolerant crop that originated in the Andes over 7000 years ago. It is adapted to different agroecological areas and can be grown from sea level to an altitude of 4000 m. The outstanding nutritional status of quinoa, with its high content of proteins, vitamins, and minerals, makes it a promising crop able to combat hunger and malnutrition in different countries in the 21st century. Quinoa cultivation has expanded from South America to Africa, Europe, Asia, and North America. Reviewing quinoa cropping practices will provide farmers with adequate recommendations for improving the agronomic and environmental sustainability of quinoa cultivation worldwide. For this reason, we conducted a systematic review of agronomic management practices in 148 field experiments conducted worldwide from 2000 to 2022. The collected data from the literature were analyzed and presented by location to determine high-performing genotypes, optimal planting dates, and other adequate cropping practices affecting quinoa performance and yield. Results showed that quinoa could be successfully cultivated in the new farming areas. Quinoa yields were higher than those reported in its place of origin, ranging from 108 kg ha-1, obtained by KU-2 in Washington State, to 9667 kg ha-1, obtained by Longli in China. Although quinoa is considered a crop with low input requirements, positive grain yield response was observed following increasing fertilization rates. Quinoa needs 2 to 4.6 kg of nitrogen to produce 1q of grain yield. In terms of phosphorus and potassium, quinoa needs 3.7 kg P2O5 and 4.3 kg K2O to produce 1 ton of total biomass. Quinoa has low water requirements (300-400 mm). However, a positive response was recorded with water quantities up to 866 mm. During our investigation, weed control in quinoa crop is still undeveloped and usually done manually. Research addressing this issue can increase quinoa yields and decrease the production cost. Downey mildew and birds’ attack are the major phytosanitary problems affecting quinoa grain yield. Other pests such as miners and aphids can also affect the health of quinoa, but their injury is not a serious problem. After the harvest, saponins found in the out layer of the seed can be removed through washing and mechanical pearling process, but the latter technic was found to be efficient and cost effective to reduce the saponin content. Our results constitute the first recommendation base for the adequate worldwide agronomic practices of quinoa crop.