�ݺ�ߣshows by User: chinthuvsaji1

�ݺ�ߣshows by User: chinthuvsaji1 / http://www.slideshare.net/images/logo.gif �ݺ�ߣshows by User: chinthuvsaji1 / Sat, 21 Oct 2017 10:18:06 GMT �ݺ�ߣShare feed for �ݺ�ߣshows by User: chinthuvsaji1 Metagenomics /slideshow/metagenomics-81043254/81043254 metagenomics-171021101806
Microbiology has experienced a transformation during the last 25 years that has altered microbiologists' view of microorganisms and how to study them. The realization that most microorganisms cannot be grown readily in pure culture forced microbiologists to question their belief that the microbial world had been conquered. We were forced to replace this belief with an acknowledgment of the extent of our ignorance about the range of metabolic and organismal diversity. ]]>
Microbiology has experienced a transformation during the last 25 years that has altered microbiologists' view of microorganisms and how to study them. The realization that most microorganisms cannot be grown readily in pure culture forced microbiologists to question their belief that the microbial world had been conquered. We were forced to replace this belief with an acknowledgment of the extent of our ignorance about the range of metabolic and organismal diversity. ]]> Sat, 21 Oct 2017 10:18:06 GMT /slideshow/metagenomics-81043254/81043254 chinthuvsaji1@slideshare.net(chinthuvsaji1) Metagenomics chinthuvsaji1 Microbiology has experienced a transformation during the last 25 years that has altered microbiologists' view of microorganisms and how to study them. The realization that most microorganisms cannot be grown readily in pure culture forced microbiologists to question their belief that the microbial world had been conquered. We were forced to replace this belief with an acknowledgment of the extent of our ignorance about the range of metabolic and organismal diversity. <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/metagenomics-171021101806-thumbnail.jpg?width=120&height=120&fit=bounds" /><br> Microbiology has experienced a transformation during the last 25 years that has altered microbiologists' view of microorganisms and how to study them. The realization that most microorganisms cannot be grown readily in pure culture forced microbiologists to question their belief that the microbial world had been conquered. We were forced to replace this belief with an acknowledgment of the extent of our ignorance about the range of metabolic and organismal diversity.

Metagenomics from Chinthu V Saji

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0 Bioprinting /slideshow/bioprinting/43045625 bioprintingppt-141228022105-conversion-gate01
Bioprinting was defined as the use of material transfer processes for patterning and assembling biologically relevant materials- molecules, cells, tissues, and biodegradable biomaterials with a prescribed organization to accomplish one or more biological function. This is a developmental biology- inspired approach to tissue engineering and is based on the assumption that tissues and organs are self- organizing systems, and that cells and especially micro tissues can undergo biological self- assembly and self- organization without any external influence in the form of instructive, supporting and directing rigid templates or solid scaffolds. Bioprinting or the biomedical application of rapid prototyping, also defined as layer- by- layer additive biomanufacturing, is an emerging transforming biomimetic technology that has potential for surpassing traditional solid scaffold- based tissue engineering. It is a rapid prototyping technology based on three dimensional, automated, computer-aided deposition of ‘‘bioink particles’’ (multicellular spheroids) into a ‘‘biopaper’’ (biocompatible gel; e.g. collagen) by a bioprinter]]>
Bioprinting was defined as the use of material transfer processes for patterning and assembling biologically relevant materials- molecules, cells, tissues, and biodegradable biomaterials with a prescribed organization to accomplish one or more biological function. This is a developmental biology- inspired approach to tissue engineering and is based on the assumption that tissues and organs are self- organizing systems, and that cells and especially micro tissues can undergo biological self- assembly and self- organization without any external influence in the form of instructive, supporting and directing rigid templates or solid scaffolds. Bioprinting or the biomedical application of rapid prototyping, also defined as layer- by- layer additive biomanufacturing, is an emerging transforming biomimetic technology that has potential for surpassing traditional solid scaffold- based tissue engineering. It is a rapid prototyping technology based on three dimensional, automated, computer-aided deposition of ‘‘bioink particles’’ (multicellular spheroids) into a ‘‘biopaper’’ (biocompatible gel; e.g. collagen) by a bioprinter]]> Sun, 28 Dec 2014 02:21:05 GMT /slideshow/bioprinting/43045625 chinthuvsaji1@slideshare.net(chinthuvsaji1) Bioprinting chinthuvsaji1 Bioprinting was defined as the use of material transfer processes for patterning and assembling biologically relevant materials- molecules, cells, tissues, and biodegradable biomaterials with a prescribed organization to accomplish one or more biological function. This is a developmental biology- inspired approach to tissue engineering and is based on the assumption that tissues and organs are self- organizing systems, and that cells and especially micro tissues can undergo biological self- assembly and self- organization without any external influence in the form of instructive, supporting and directing rigid templates or solid scaffolds. Bioprinting or the biomedical application of rapid prototyping, also defined as layer- by- layer additive biomanufacturing, is an emerging transforming biomimetic technology that has potential for surpassing traditional solid scaffold- based tissue engineering. It is a rapid prototyping technology based on three dimensional, automated, computer-aided deposition of ‘‘bioink particles’’ (multicellular spheroids) into a ‘‘biopaper’’ (biocompatible gel; e.g. collagen) by a bioprinter <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/bioprintingppt-141228022105-conversion-gate01-thumbnail.jpg?width=120&height=120&fit=bounds" /><br> Bioprinting was defined as the use of material transfer processes for patterning and assembling biologically relevant materials- molecules, cells, tissues, and biodegradable biomaterials with a prescribed organization to accomplish one or more biological function. This is a developmental biology- inspired approach to tissue engineering and is based on the assumption that tissues and organs are self- organizing systems, and that cells and especially micro tissues can undergo biological self- assembly and self- organization without any external influence in the form of instructive, supporting and directing rigid templates or solid scaffolds. Bioprinting or the biomedical application of rapid prototyping, also defined as layer- by- layer additive biomanufacturing, is an emerging transforming biomimetic technology that has potential for surpassing traditional solid scaffold- based tissue engineering. It is a rapid prototyping technology based on three dimensional, automated, computer-aided deposition of ‘‘bioink particles’’ (multicellular spheroids) into a ‘‘biopaper’’ (biocompatible gel; e.g. collagen) by a bioprinter

Bioprinting from Chinthu V Saji

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