基因工程技术在食品品质改良中的应用

概述了用基因工程技术改良食品的食用品质,提高食品加工性能的研究和应用现状。     

微藻基因工程概述

微藻细胞代谢产生的多种代谢产物在食品、医药、饲料、能源等领域具有重要应用。随着基因工程技术的发展,以及基因测序成本逐年降低,一些微藻基因组陆续被公布,使得根据人类的需求特异性地对微藻进行遗传改造成为可能,并展现出广阔的应用前景。针对不同的介导体系和基因编辑技术,对微藻基因工程改造手段进行总结及展望。     

推动食品生物技术及产业快速创新发展

<正>食品生物技术,是指生物技术在食品领域中的应用,包括利用传统生物技术进行食品发酵和酿造,以及利用现代生物技术,如基因工程、酶工程、细胞工程、现代发酵工程、组学技术等,进行食品及食品原料的生产、加工和改良。食品生物技术作为一项极富潜力和发展空间的高新技术,以生命科学为基础,以工程技术为手段,在食品工业的现代发展中发挥着重要的推动作用。食品生物技术是一门极具包容性和关联性的综合学科,包括分子生物学、细胞生物学、微生物学、免疫学、     

基因工程的发展现状与前景展望

1972年,PaulBerg构建了世界上第一个重组DNA分子,自此,基因工程便诞生了,并很快掀起了基因工程研究的热潮。27年来,基因工程技术已获得了突飞猛进的发展,取得了许多世人瞩目的成就,对农业生产、医疗卫生、轻工食品和环境卫生等诸多方面产生了巨大的影响,正在成为生物学研究的最前沿学科。科学家们预言,以基因工程技术为主体的生物技术将成为21世纪新技术的主导技术之一。     

基因工程技术在植物品质改良中的应用(综述)

从淀粉品质改良、蛋白质品质改良、增强果蔬食品保鲜性能、提高植物营养保健成分和植物疫苗生产等5个方面,总结基因工程技术所取得的成就。     

基因工程改良作物营养品质的研究

综述了近10年来采用基因工程技术改良作物蛋白质、糖类、脂类营养成分研究的最新发展,尤其对作物蛋白质含量及氨基酸组分改良方面进行了详细描述;并简要介绍了基因工程食品可能存在的不安全性问题及解决的办法。     

基因工程技术在建立噬菌体抗性机制研究中的应用

在自然发生的噬菌体抗性机制的基础上,应用基因工程技术可以建立广泛的噬菌体抗性机制,为有效解决噬菌体感染问题提供了新的策略。噬菌体编码的抗性、反义RNA技术、自杀陷阱及限制/修饰系统的应用是近年来发展起来的几种抗噬菌体策略,着重对其作用机制、研究进展及其意义作一介绍。同时指出应用基因工程技术构建的噬菌体抗性菌株应用于食品发酵工业中所存在的问题,并对其应用前景作了展望。     

重要谷类种子贮藏蛋白的特性及改良研究

在成熟谷类种子中,总蛋白约为种子干重的7％～16％,其中大部分为贮藏蛋白。这些贮藏蛋白对于人类和牲畜所需要的营养质量以及在食品加工中都有重要的影响。本文对一些重要谷类种子贮藏蛋白的组成特性以及利用基因工程技术提高谷类种子蛋白质含量和质量进行了全面综述。此外,还简要介绍了在利用基因工程改良谷物种子品质中可能产生的食品安全性问题、如何增加外源基因的表达量和全面提高谷类种子蛋白质含量以及解决的办法。     

大豆过敏蛋白与品种改良

食物过敏是一个全世界关注的公共卫生问题。大豆蛋白在食品加工业的广泛应用,对大豆敏感人群带来了潜在的威胁。如何降低大豆过敏原含量提升大豆食品安全已成为日益关注的问题。大豆种子过敏蛋白包括种子贮存蛋白、结构蛋白和防御相关蛋白,其中7S 伴球蛋白的多肽片段Gly m Bd 28K, Gly m Bd 30K和Gly m Bd 60K是三种主要的过敏原。目前通过对过敏蛋白的理化性质、过敏原性和基因结构的认识,运用食品加工工艺、传统育种及基因工程技术等方法,在减少大豆和大豆产品的过敏原性方面已取得一定的进展。本文拟从大豆过敏原的分类、主要过敏原Gly m Bd 28K和Gly m Bd 30K的理化性质及基因结构、大豆过敏蛋白在遗传改良中的应用对大豆过敏蛋白进行综述。     

基因工程在食品工业中的应用

阐述了基因工程的技术溯源,论述了基因工程在食品工业方面的应用,提出与生产实践相结合的实例;详细介绍了基因工程食品的由来,展望了基因工程技术在食品工业领域中的美好发展前景.     

Recent trends and technological development in plasma as an emerging and promising technology for food biosystems

The rising need for wholesome, fresh, safe and “minimally-processed” foods has led to pioneering research activities in the emerging non-thermal technology of food processing. Cold plasma is such an innovative and promising technology that offers several potential applications in the food industry. It uses the highly reactive, energetic and charged gas molecules and species to decontaminate the food and package surfaces and preserve the foods without causing thermal damage to the nutritional and quality attributes of food. Cold plasma technology showed promising results about the inactivation of pathogens in the food industry without affecting the food quality. It is highly effective for surface decontamination of fruits and vegetables, but extensive research is required before its commercial utilization. Recent patents are focused on the applications of cold plasma in food processing and preservation. However, further studies are strongly needed to scale up this technology for future commercialization and understand plasma physics for getting better results and expand the applications and benefits. This review summarizes the emerging trends of cold plasma along with its recent applications in the food industry to extend shelf life and improve the quality of food. It also gives an overview of plasma generation and principles including mechanism of action. Further, the patents based on cold plasma technology have also been highlighted comprehensively for the first time.     

超临界萃取技术及其在食品工业中的应用进展

本文概述了超临界二氧化碳萃取技术,简要介绍了其在食品工业中的最新运用动态,并对超临界二氧化碳萃取技术作了展望。     

膨化技术及其在食品工业中的应用

膨化技术作为一种新型食品生产技术,正逐步在食品工业中得到广泛的应用。本文就现在国内常用的油炸膨化技术、挤压膨化技术、微波膨化技术、低温气流膨化技术和CO2膨化技术予以阐述。     

Commodities into food

It is not surprising that past predictions of the extent of adoption of new technology by the food and agricultural industries have only been partly realized. This is a result of the difficulty of forecasting the take-up of technology that is capable of being transferred from other industries, for example, process control methods and the advent of new packaging materials. Most technology that is adopted is normally incremental over the existing technology and forecasting of this type is best done by specific experts within the industry. Factors which influence uptake of technology in the food industry include not only the available technology, but also the supply of raw materials, economics and disposable income, food habits, health and nutrition and market requirements. In addition to these there is legislation, which imposes compositional, labelling and trade requirements on grower, processor and retailer. New products and processes are determined by all these factors, the overriding influence being the consumer's requirement for palatable and nutritious foods that provide value for money. In the cereals-processing industry significant developments have taken place in the provision of U.K. wheat varieties for breadmaking. The U.K. is now in the position where the bulk of its breadmaking wheats are homegrown. Further advances can be make by investing in applied research into those characteristics of bread wheats which are determinants of good bread flours, that in turn will help in the provision of suitable bread wheat varieties. A less traditional area is that of flour fractionation.(ABSTRACT TRUNCATED AT 250 WORDS)     

Applications of nonthermal plasma technology on safety and quality of dried food ingredients

Cold plasma technology is an efficient, environmental-friendly, economic and noninvasive technology; and in recent years these advantages placed this novel technology at the centre of diverse studies for food industry applications. Dried food ingredients including spices, herbs, powders and seeds are an important part of the human diet; and the growing demands of consumers for higher quality and safe food products have led to increased research into alternative decontamination methods. Numerous studies have investigated the effect of nonthermal plasma on dried food ingredients for food safety and quality purposes. This review provides critical review on potential of cold plasma for disinfection of dried food surfaces (spices, herbs and seeds), improvement of functional and rheological properties of dried ingredients (powders, proteins and starches). The review further highlights the benefits of plasma treatment for enhancement of seeds performance and germination yield which could be applied in agricultural sector in near future. Different studies applying plasma technology for control of pathogens and spoilage micro-organisms and modification of food quality and germination of dried food products followed by benefits and current challenges are presented. However, more systemic research needs to be addressed for successful adoption of this technology in food industry.     

未来食品的低碳生物制造

受到人口增长过快、社会经济发展水平不平衡、人口老龄化和不健康饮食方式等影响,人类面临着食品和营养缺乏、部分人群中营养相关疾病高发等问题。同时,社会低碳发展的需求呼唤一种可持续的食物供给模式。因此,既能满足消费者口感和营养需求,又是绿色可持续食物供给模式的技术,例如功能糖、人造肉等未来食品技术,受到了广泛的关注。近年,新兴的生物制造技术及产品得到了迅猛发展,将会支撑形成绿色、低碳的未来食品产业,引发传统生产模式的深刻变革,是新兴生物经济的重大战略发展方向。本文聚焦于未来食品——功能糖、微生物蛋白及人造肉等关键辅配料的生物制造技术研究,追踪其在细胞工厂构建、工业环境下菌种测试与过程优化和衍生产品开发等研究的最新进展,展望未来的发展趋势,旨在为微生物制造未来食品的产业发展提供指导。     

传统与未来的碰撞：食品发酵工程技术与应用进展

随着生物技术的飞速发展,作为食品生物工程的主要组成部分,食品发酵工程技术不断升级,在传统发酵食品的菌种、发酵过程、产品品质得到改善的同时,生物制造的功能食品组分、未来食品等新型产品也应运而生。首先概述了由生物技术和信息技术的进步带来的食品发酵研究手段与生产方式的多层面变革,并重点阐释了利用食品合成生物学设计构建细胞工厂的思路和方法,以及食品生物工程在微生物分析、过程工程和分离工程方面的智能化进程。其次,介绍了现代食品生物工程技术在改善传统发酵食品品质及安全性、生产功能食品组分、添加剂和酶制剂、创制未来食品和开发新型益生食品方面的应用进展。最后,对全球和我国食品发酵产业面临的挑战和未来发展趋势进行了总结和展望,以期为食品发酵的技术革新和工业化应用提供参考。     

OBPC Symposium: maize 2004 &; beyond—Can agricultural biotechnology contribute to global food security?

Summary Bioengineering approaches provide unprecedented opportunities for reducing poverty, food insecurity, child malnutrition, and natural resource degradation. Genetic engineering offers outstanding potential to increase the efficiency of crop improvement. Thus agricultural biotechnology could enhance global food production and availability in a sustainable way. Small farmers in developing countries are faced with many problems and constraints which biotechnology may assist. Yet, there are varying levels of opposition to the use of this technology in most countries and it is especially intense in Europe. While there is certain public apprehension with the use of bioengineering in food improvement, the primary hurdles facing this technology are the stringent and burdensome regulatory requirements for commercialization, opposition from the special interest groups, apprehension by the food industry especially with the whole foods, and trade barriers including rigid policies on traceability and labeling. Bioengineered crops such as soybean, maize, cotton, and canola with a few traits have already made a remarkable impaet on food production and environmental quality. But, in the developing world, bioengineering of crops such as bananas, cassava, yams, sweet potatoes, sorghum, rice, maize, wheat, millet, and legumes, along with livestock, can elearly contribute to global food security. However, the integration of biotechnology into agricultural research in developing countries faces many challenges which must be addressed: financial, technical, political, environmental, activism, intellectual-property, biosafety, and trade-related issues. To ensure that developing countries can harness the benefit of this technology with minimal problems, concerted efforts must be pursued to create an awareness of its potential benefits and to address the concerns related to its use through dialog among the various stakeholders: policy makers, scientists, trade groups, food industry, consumer organizations, farmer groups, media, and non-governmental organizations. Biotechnology holds great promise as a new tool in the scientific toolkit for generating applied agricultural technologies; however, per se it is not a panacea for the worlds problems of hunger and poverty.     

近红外光谱技术在水果成熟期预测中的应用(综述)

近红外光谱技术以快速、准确和多组分同步分析等优势,近年来在水果果实发育、成熟期预测和品质检测等方面应用广泛,并在果实品质无损检测分析技术研究方面取得重要进展。本文综述近红外光谱技术的基本原理和特点,分析近红外光谱技术在果实成熟期预测中的研究现状和存在问题,并提出今后研究方向。