Animal breeding in the age of biotechnology: the investigative pathway behind the cloning of Dolly the sheep

History and Philosophy of the Life Sciences - This paper addresses the 1996 cloning of Dolly the sheep, locating it within a long-standing tradition of animal breeding research in Edinburgh. Far...     

Progress in the biotechnology of trees

An increasing world population and rise in demand for tree products, especially wood, has increased the need to produce more timber through planting more forest with improved quality stock. Superior trees are likely to arise from several sources. Firstly, forest trees can be selected from wild populations and cloned using macropropagation techniques already being investigated for fruit tree rootstocks. Alternatively, propagation might be brought aboutin vitro through micropropagation or sustained somatic embryogenesis, with encapsulation of the somatic embryos to form artificial seeds. Tree quality could be improved through increased plant breeding and it is likely that experienced gained, to date, in the breeding of fruit species will be useful in devising strategies for forest trees. Since the development of techniques to regenerate woody plants from explant tissues, cells and protoplasts, it is now feasible to test the use of tissue culture methods to bring about improvements in tree quality. Success has already been achieved for tree species in the generation of somaclonal and protoclonal variation, the formation of haploids, triploids and polyploids, somatic hybrids and cybrids and the introduction of foreign DNA through transformation. This review summarizes the advances made so far in tree biotechnology, and suggests some of the directions that it might take in the future.     

Microfluidics in biotechnology

Microfluidics enables biotechnological processes to proceed on a scale (microns) at which physical processes such as osmotic movement, electrophoretic-motility and surface interactions become enhanced. At the microscale sample volumes and assay times are reduced, and procedural costs are lowered. The versatility of microfluidic devices allows interfacing with current methods and technologies. Microfluidics has been applied to DNA analysis methods and shown to accelerate DNA microarray assay hybridisation times. The linking of microfluidics to protein analysis techologies, e.g. mass spectrometry, enables picomole amounts of peptide to be analysed within a controlled micro-environment. The flexibility of microfluidics will facilitate its exploitation in assay development across multiple biotechnological disciplines.     

World trends in the development of biotechnology

The role of biotechnology in the solution of the production problem and creation of new energy source is discussed. Certain operations of biotechnological processes are considered. A system approach to train specialists in the field of biotechnology is suggested.     

Downstream processing in the biotechnology industry

The biotechnology industry today employs recombinant bacteria, mammalian cells, and transgenic animals for the production of high-value therapeutic proteins. This article reviews the techniques employed in this industry for the recovery of these products. The methods reviewed extend from the centrifugation and membrane filtration for the initial clarification of crude culture media to the final purification of the products by a variety of membrane-based and chromatographic methods. The subject of process validation including validation of the removal of bacterial and viral contaminants from the final products is also discussed with special reference to the latest regulatory guidelines.     

Fulfilling the promise of biotechnology

Genetic engineering has produced pharmaceuticals, disease-resistant plants, cloned animals and research and industrial products. While the comparably mature field of medical biotechnology now reveals its true potential, marine biotechnology is still in the realm of the future. As we explore the earth for new sources of natural chemicals, we now search the waters. Myriad organisms, most unknown to us, live there. Many produce compounds that can be commercialized, or the organisms themselves may be commercialized, through genetic engineering methods. For decades, scientists studied the ocean depths searching for unique molecules and organisms. But not until the early 1980s was there a synthesis uniting marine natural products, ecology, aquaculture and bioremediation research under the heading of marine biotechnology. As harvesting enough products from marine sources to produce sufficient amounts, even for study, is nearly impossible, we need to use genomics techniques to identify biologically active compounds. As we damage our oceanic ecosystems through pollution, overfishing and destructive fishing methods, opportunities to learn more about marine organisms and their commercial potential may be limited. Although governments and intergovernmental agencies are committed to funding and expanding oceanic research, more funding is needed to discover and study the ocean's vast, unplumbed resources.     

Environmental biotechnology in the postgenomics era

The sequencing of the human genome and many microbial genomes has provided new opportunities to study the environmental impact on life processes, leading to development of new technologies that can be protected by patenting. Development of such new technologies has, however, led in some cases to judicial intervention because of their controversial nature. This article illustrates some of the trends in postgenomics biotechnology development and the attendant legal and ethical considerations.     

Magnetic separations in biotechnology

Magnetic separations are probably one of the most versatile separation processes in biotechnology as they are able to purify cells, viruses, proteins and nucleic acids directly from crude samples. The fast and gentle process in combination with its easy scale-up and automation provide unique advantages over other separation techniques. In the midst of this process are the magnetic adsorbents tailored for the envisioned target and whose complex synthesis spans over multiple fields of science. In this context, this article reviews both the synthesis and tailoring of magnetic adsorbents for bioseparations as well as their ultimate application.     

生物技术在农业中的应用

简要阐述了生物技术发展的几个阶段,包括传统生物技术和新兴生物技术的发展状况,着重论述了生物技术在农业上的应用进展,将基因工程、细胞工程、发酵工程和酶工程的含义及其应用状况进行了描述,展望了生物技术在农业上的应用前景。     

Magnetic separations in biotechnology

Magnetic separation techniques provide probably the most rapid and convenient method of separating certain particles from dilute suspensions, especially those that might block columns or filters. This and other applications of magnetism, including cell sorting and product recovery are discussed.