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市場調查報告書

工業用海洋生物技術的未來:∼2025年

The Future of Marine Biotechnology for Industrial Applications to 2025

出版商 Smithers Rapra 商品編碼 342160
出版日期 內容資訊 英文
商品交期: 最快1-2個工作天內
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工業用海洋生物技術的未來:∼2025年 The Future of Marine Biotechnology for Industrial Applications to 2025
出版日期: 2015年10月23日 內容資訊: 英文
簡介

工業用海洋生物技術市場中,化妝品產業上海洋萃取酵素的新應用,及利用大型藻類和微藻類的生質燃料生產是最重要的推動市場成長要素。但同時需要莫大基礎設施投資可能將成為阻礙市場擴大的要素。

本報告涵括工業用海洋生物技術的全球市場,提供您推動市場成長要素,阻礙因素,技術趨勢和飛躍性的新技術,市場競爭環境,以及法律規章等總括性檢驗,以及現行市場分析與2025年的市場預測。

第1章 摘要整理

  • 海洋生物技術
  • 海洋資源及產品
  • 核心技術
  • 產業的發達
  • 推動市場成長要素及阻礙因素
  • 市場
  • 技術趨勢
  • 經營模式
  • 企業聯盟成功的關鍵

第2章 序論及調查手法

  • 本報告的序論
  • 本報告的目的及調查範圍
  • 調查手法
  • 定義一覽

第3章 海洋生物技術的價值鏈

  • 序論
  • 海洋生物技術的指南
  • 海洋資源
    • 海生菌類
    • 微藻類
    • 大型藻類
    • 珊瑚及海綿
    • 海生病毒
  • 核心技術
    • 微生物的濃縮,分離,及培養
    • 不依賴培養的技術
    • 大規模設備
  • 產品及市場
    • 食品及飼料
    • 能源
    • 生物材料,工業產品,及做法
    • 環境
    • 健康及健全性
  • 產業的發達
  • 推動市場成長要素及阻礙因素
  • 生物技術產業上投資和經濟

第4章 技術趨勢及顛覆性新技術

  • 研究開發趨勢
    • 體學工具
    • 高通量分子分析
    • 代謝工程及合成生物學
    • 海生微生物的培養
    • 對海洋生物煉製廠的意願
    • 得到和保護貴重的地球資源
    • 守護環境
    • 全球的糧食供給
  • 顛覆性新技術
    • 單細胞基因工程學技術
    • 奈米孔DNA測序技術
    • 蛋白質體學的進步
    • 生物資源調查的新培養系統
    • 共生或混合培養系統
    • 探索有助於生物煉製的酵素
    • 微生物的性狀操作
    • 海洋性營養補充品及機能性食品以及飼料
    • 生物材料領域及奈米技術領域的進步
    • Operational clustering and integration

第5章 海洋生物技術的企業聯合及合作

  • 主要企業
    • 微藻類:生質燃料及其他的應用
    • 食品及飼料的成分及添加物
    • 酵素
  • 經營模式
  • 瞄準成長的企業聯盟

第6章 達到2025年的市場預測

  • 海洋生物技術產業到2025年前將如何發展?
  • 價值鏈預測
  • 市場預測

第7章 法律規章情形

  • 海洋基因研究材料的連結
  • 智慧財產權

附表·附圖

目錄

The Future of Marine Biotechnology for Industrial Applications to 2025 states that key drivers for the market are new applications of marine derived enzymes in the cosmetics industry and use of marine algae and micro algae in biofuel production. The need for major infrastructure investments may be a restraining factor for the market. North America has the largest market for marine biotechnology, mainly focused on the production of algae-derived bioenergy. However, Asia-Pacific is the fastest growing market due to the aquaculture and hydrocolloid segments. Europe is also one of the leading regions for growth and is poised to emerge as a major regional market thanks to its underexplored marine resources.

Our exclusive content:

  • In-depth exploration ofthe marine biotechnology for industrial applications market
  • Analysis of key technology trends expected to impact the industry
  • Detailed ten-year forecasts on important developments in the marine biotechnology value chain

What methodology is used?

The Future of Marine Biotechnology for Industrial Application to 2025 completed an extensive literature search, mainly using electronic databases, scientific publications, industry journals and trade publications. Also very useful were reports of the OECD, of the European Science Foundation, the European Commission and strategic plans of various governments whose countries have a large maritime economic zone. Further, annual reports, presentations of the major players at leading conferences on marine biotechnology and the bio-based economy, and public announcements or press releases of companies and funding agencies were used. Direct contacts were also established with marine biotechnology actors from all continents.

What will you discover?

  • In-depth analysis of the marine biotechnology value chain broken down by sources, technologies and markets
  • Key alliances and partnerships within the marine biotechnology market
  • Exclusive industry data based on an in-depth analysis of literature, including industry journals and scientific publications

Table of Contents

Executive summary

  • Marine biotechnology
  • Marine sources and products
  • Core technologies
  • Industry development
  • Drivers and barriers
  • Markets
  • Technology trends
  • Business models
  • Partnerships are key

Introduction and methodology

  • Introduction to the report
  • Report objective and scope
  • Methodology
  • List of definitions

The marine biotechnology value chain

  • Introduction
  • Marine biotechnology -- a primer
  • Marine sources
    • Marine fungi
    • Microalgae
    • Macroalgae
    • Corals and sponges
    • Marine viruses
  • Core technologies
    • Enrichment, isolation and cultivation of microorganisms
    • Culture-independent techniques
    • Large scale implementation
  • Products and markets
    • Food and feed
    • Energy
    • Biomaterials, industrial products and processes
    • Environment
    • Health and well-being
  • Industry development
  • Drivers and barriers
  • Investment and economics in industrial biotechnology

Technology trends and disruptive technologies

  • R&D trends
    • Omic tools
    • High throughput molecular analysis
    • Metabolic engineering and synthetic biology
    • Cultivation of marine organisms
    • Towards a marine biorefinery
    • Accessing and preserving valuable georesources
    • Taking care of our environment
    • Feeding the world
  • Disruptive technologies
    • Single cell genomics methods
    • Nanopore DNA sequencing technology
    • Progress in proteomics
    • New culture systems in bioprospecting
    • Co- or mixed culture systems
    • Mining for biorefinery-relevant enzymes
    • Tailored traits to microorganisms
    • Marine nutraceuticals and functional foods and feeds
    • Advancing the fields of biogenic materials and nanotechnology
    • Operational clustering and integration

Alliances and partnerships in marine biotechnology

  • Some key companies
    • Microalgae: biofuels and beyond
    • Food and feed ingredients and additives
    • Enzymes
  • Business models
  • Partnering for growth

Forecasts to 2025

  • How will the marine biotechnology industry develop to 2025?
  • Value chain forecasts
  • Market forecasts

Regulatory Landscape

  • Access to marine genetic material
  • Intellectual property rights

Tables and figures

  • Perspectives of marine biotechnology. Adapted from Norgenta and DSN (2012).
  • Simplified depiction of the marine biotechnology valuechain. At some point, the stages or processes in the value chain may become specific to other biotechnology or industry sectors
  • Projections for global marine biotechnology market
  • Technology trends in marine biotechnology
  • Perspectives of marine biotechnology. Adapted from Norgenta and DSN (2012)
  • The tree of life. Adapted
  • Omic approaches in marine biotechnology
  • Typical feed conversion ratios (kg body mass gain per kg feed intake) for farmed animals
  • World capture fisheries and aquaculture production. Data from the FAO.13
  • Fish meal production. Data from International Fishmeal and Fish Oil Organisation
  • Potential applications of biotechnology in the recovery of oil from reservoirs
  • Simplified depiction of the marine biotechnology valuechain. At some point, the stages or processes in the value chain may become specific to other biotechnology or industry sectors
  • Estimates of the value of the global marine biotechnology sector
  • Schematics of the metagenomics process
  • Core metabolic network of biochemical reactions. Circles indicate metabolites and lines indicate conversions by enzymes
  • Example of a synthetic pathway implemented in a microorganism, from central carbon pathway to isoprene
  • Schematics of a microalgae biorefinery concept
  • Biorefinery concept using seaweeds
  • Biofouling formation mechanism and timings
  • Single-cell genomics pipeline
  • Illustration of a singlestranded DNA homopolymer translocating through a silicon nitride nanopore (Credit: University of Pennsylvania)
  • Cost of genome sequencing. Post-Sanger sequencing created a significant decrease in 2008. The nanopore technology will create a similar effect dramatically decreasing the current DNA sequencing costs
  • Structures of some marine based polysaccharides as compared to cellulose
  • Mangrove ecosystem (credit: National Oceanic and Atmospheric Administration, USA)
  • Comparison of classical biodiesel production from microalgae with the direct process for renewable diesel production using engineering microorganism
  • Nanotechnology markets
  • Diatoms capable of synthesizing biogenic silica (credit: U.S. National Oceanic and Atmospheric Administration)
  • Integrated seawater energy and agriculture system
  • Schematic representation of Alltech's integrated farming concept
  • Algenol's vertical reactors
  • Projections for global marine biotechnology market
  • Market for marine-derived drugs
  • Market for omega-3 fatty acids
  • Markets for carrageenan and alginate
  • The oceans -- the largest ecosystem on earth
  • The census of marine life
  • Key facts about marine microorganisms
  • Current and potential commercial uses of microalgae
  • Current and potential commercial uses of macroalgae
  • Important marine sources and research areas
  • Challenges for the largescale implementation of culture systems for marine microorganisms
  • Applications of marine biotechnology in food and feed sectors
  • Energy and derived applications of marine biotechnology
  • Application of marine biotechnology in the environmental sector
  • The marine pharmaceutical clinical pipeline
  • Examples of currently marketed marine biotechnology cosmetic products
  • Marine biotechnology applications in the health and well-being markets
  • Drivers of marine biotechnology
  • Drivers and barriers for marine biotechnology
  • Omics research trends in marine biotechnology
  • Trends in high-throughput molecular analysis
  • Systems biology trends for marine biotechnology
  • Challenges impacting the ability to culture novel marine microorganisms
  • Compared advantages and disadvantages of open pond vs. closed photobioreactors for cultivation of microalgae
  • Compared advantages and disadvantages of cultivation of seaweeds in the wild vs. in landbased aquaculture
  • Trends in the cultivation of marine biotechnology
  • Trends in R&D for a microalgae biorefinery
  • Main differences between lignocellulosic and seaweed biomass
  • Typical composition of seaweeds
  • Trends in R&D for a macroalgae biorefinery
  • Bioshere meets geosphere
  • Increase in required shaft power in a U.S. Navy destroyer with a range of coating and fouling conditions at two speeds with reference to an hydraulically smooth surface
  • Trends in R&D for the contribution of marine biotechnology to environmental applications
  • Trends in R&D for a food and feed
  • Major advances in proteomics
  • Limitations inherent to the culture of marine bacteria and novel culture techniques to overcome them
  • R&D priorities in co- or mixedculture systems
  • Potential of marine-derived enzymes for the deconstruction of biomass (both terrestrial and marine)
  • R&D challenges for marine nutraceuticals and functional foods
  • R&D challenges for marinederived feeds
  • Examples of nanomaterials and applications from marine biotechnology
  • Cellana quick-facts
  • Sapphire Energy quick-facts
  • Joule Unlimited quick-facts
  • Algenol quick-facts
  • Algenol quick-facts
  • The Martek story
  • Fermentalg quick-facts
  • Calysta quick-facts
  • Biomar quick-facts
  • Some examples of partnerships in marine biotechnology
  • Some examples of acquisitions in marine biotechnology
  • Asia, a region at the core of the future of marine biotechnology
  • Summary of value-chain forecasts
  • The United Nations Convention on the Law of the Sea
  • The Convention on Biological Diversity
  • The Nagoya Protocol
  • Copyright applicable to databases
  • Can marine genetic resources obtained in high seas be protected?
  • Pitfalls of access and benefit sharing agreements
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