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市場調查報告書
商品編碼
1410249
農業基因組學市場:2023年至2028年預測Agrigenomics Market - Forecasts from 2023 to 2028 |
預計全球農業基因組學市場在預測期內將以 15.88% 的複合年成長率成長,從 2021 年的 3,346,647,000 美元增至 2028 年的 9,388,718,000 美元。
基因組學和定序技術的不斷進步為農業基因組學公司開闢了新的視野。在人口成長和永續農業發展導致的全球糧食需求不斷成長的推動下,農業基因組學市場在可預見的未來可能會持續成長。農業基因組學在多種領域都有應用,包括作物和牲畜育種、基因工程以及應對病蟲害挑戰。 HiFi 定序儀在提供高保真基因組資訊、進一步推動農業基因組學領域發揮關鍵作用。
農業基因Start-UpsSingrow 在新加坡以新的室內農場的形式開設了一個研發中心。該公司策略性地解決了在資源有限以及氣候變遷驅動的乾旱和火災等自然災害影響日益加大的時代與糧食種植相關的複雜性。作為其成長策略的一部分,Singrow 正在積極探索向馬來西亞和泰國擴張的機會。預計此類市場開拓將在預測期內促進農業基因組學市場的成長和需求。
自 20 世紀中葉以來,世界人口增加了兩倍多,到 2022 年 11 月中旬達到 80 億,而 1950 年估計為 25 億。據預測,未來 30 年內世界人口將增加近 20 億,到 2050 年從目前的 80 億躍升至 97 億,到 2080 年代中期將達到 104 億。這種前所未有的成長正在推動糧食需求的增加,並造成飢餓和營養不良的危機。為了應對這些挑戰,迫切需要加強永續生產方法並為世界日益嚴重的糧食問題制定解決方案。
農業基因組學和與理想性狀相關的遺傳標記等技術使農民、育種者和研究人員能夠快速識別和利用重要的遺傳訊息。這有助於在種植和育種實踐中做出明智的決策,為更有效率和永續的食品管理系統提供途徑。
根據聯合國糧食及農業組織 (FAO) 的預測,到 2050 年,糧食產量需要增加 60%,才能充分養活世界人口(預計將達到 93 億)。為了實現農作物生產的永續成長,我們需要採用與生態系統更和諧的技術。這包括最大限度地減少對外部投入的依賴、應用技術和幫助農民管理日益不穩定的天氣模式。農業基因組學可以創造水產養殖、牲畜、植物、家禽和伴同性動物高生產力的生態系統。作物和牲畜育種、基因工程以及減少病蟲害的努力可以幫助識別與免疫、代謝解毒和農藥抗性等性狀相關的新基因。
農業基因組學的使用在美國正在增加,因為它有助於改善作物健康和產量。此外,由於該國對商業性生產作物的需求不斷增加,採用率逐年增加。例如,根據美國農業部 (USDA) 的數據,美國90% 的玉米、陸地棉花和大豆現在都是使用基因改造種子生產的。此外,該國不斷成長的人口也迫使農業增加產量以滿足國內需求。目前,農業產業面臨氣候變遷、水資源短缺、土地劣化挑戰,農業產業難以滿足日益成長的需求。
根據美國農業部(USDA)統計,2020年農業用地面積為8.9666億英畝,2021年增加至8.953億英畝,減少130萬英畝。隨著都市化進程的加快,可用於農業種植的土地面積不斷減少,耕地面積不斷減少,在預測期內需要提高作物產量的解決方案,農業基因組學市場將在未來幾年持續成長。這些年。
The global agrigenomics market is projected to grow at a CAGR of 15.88% over the forecast period, increasing from US$3,346.647 million in 2021 to US$9,388.718 million by 2028.
Ongoing technological strides in genomics and sequencing are opening fresh prospects for companies operating in agrigenomics. The agrigenomics market will experience sustained growth in the foreseeable future, propelled by the rising global demand for food due to growing population size and the development of sustainable agricultural practices. Agrigenomics finds application in various areas, including crop and livestock breeding, genetic engineering, and addressing challenges related to pests and diseases. HiFi sequencing plays a crucial role in delivering high-fidelity genomic information, further advancing the field of agrigenomics.
Upcoming innovations and research will further fuel the growth of this field, Singrow, an agrigenomics startup company, has inaugurated its primary research and development hub in the form of a new indoor farm in Singapore. The company is strategically addressing the complexities associated with cultivating food in an era marked by resource constraints and the escalating impact of climate change-induced natural disasters like droughts and fires. Singrow is actively exploring opportunities for expansion into Malaysia and Thailand as part of its growth strategy. Developments such as these are anticipated to boost the market growth and demand for agrigenomics in the forecasted period.
The global population has surged to over triple its mid-twentieth-century size, reaching 8.0 billion in mid-November 2022 compared to the estimated 2.5 billion in 1950. Projections indicate that the world's population is set to increase by nearly 2 billion individuals within the next 30 years, soaring from the current 8 billion to 9.7 billion by 2050 and potentially peaking at around 10.4 billion in the mid-2080s. This unprecedented growth has spurred a heightened demand for food, triggering hunger and malnutrition crises. To address these challenges, there is a pressing need to enhance sustainable production methods and devise solutions for the world's expanding food issues.
Utilizing technologies like Agricultural genomics, and genetic markers associated with desirable traits, farmers, breeders, and researchers can swiftly identify and leverage key genetic information. This helps to make informed decisions in cultivation and breeding practices, offering a pathway to more efficient and sustainable food management systems.
According to projections compiled by the Food and Agriculture Organization (FAO), a 60 percent increase in food production will be necessary by 2050 to adequately feed a global population expected to reach 9.3 billion. Achieving sustainable growth in crop production involves employing techniques that align more harmoniously with ecosystems. This includes minimizing the reliance on external inputs, applying technologies, and assisting farmers in managing the increasingly erratic weather patterns. Agricultural genomics can create an ecosystem for high productivity in aquaculture, livestock, plants, poultry, and companion animals. It can assist in identifying novel genes associated with traits such as immunity, metabolic detoxification, and resistance to pesticides, including crop or livestock breeding, genetic engineering, and efforts to mitigate pests and diseases.
The use of agrigenomics is increasing in the USA, as it helps in improving crop health, and the yield of the harvest is also good. Moreover, adoption has increased over the years as the demand for commercially produced crops is increasing in the country. For instance, according to the United States Department of Agriculture (USDA), currently, 90% of the USA's corn, upland cotton, and soybean are produced using genetically engineered seeds. Additionally, the increasing population in the country is also putting pressure on agriculture to increase production, to satisfy the country's demand. The agriculture industry these days is facing issues such as climate change, water scarcity, and land degradation which is making it difficult for the agricultural industry to meet the increased demand, which is one of the major reasons contributing to market growth for agrigenomics.
According to the United States Department of Agriculture (USDA), the area of land in farms in 2020 was 89,66,00,000 acres, which increased to 89,53,00,000 in 2021, which reduced by 13,00,000 acres. The decreasing land area available for agriculture cultivation and less arable land due to increasing urbanization is demanding a solution that can increase yield in the projected period, which is expected to boost the market for agrigenomics in the coming years.