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200 1 $aContra Hypocritas$fPoggio Bracciolini$ga cura di Davide Canfora
210   $aRoma$cEdizioni di Storia e Letteratura$d2008
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101 0 $aeng
135   $aurmn|---annan
181   $ctxt$2rdacontent
182   $cc$2rdamedia
183   $acr$2rdacarrier
200 00$aThe Application of Viruses to Biotechnology
210   $aBasel, Switzerland$cMDPI - Multidisciplinary Digital Publishing Institute$d2021
215   $a1 online resource (296 p.)
311 08$a3-0365-2539-4 
311 08$a3-0365-2538-6 
330   $aViruses are microscopic agents that exist worldwide and are present in humans, animals, plants, and other living organisms in which they can cause devastating diseases. However, the advances of biotechnology and next-generation sequencing technologies have accelerated novel virus discovery, identification, sequencing, and manipulation, showing that they present unique characteristics that place them as valuable tools for a wide variety of biotechnological applications. Many applications of viruses have been used for agricultural purposes, namely concerning plant breeding and plant protection. Nevertheless, it is interesting to mention that plants have also many advantages to be used in vaccine production, such as the low cost and low risks they entail, showing once more the versatility of the use of viruses in biotechnology. Although it will obviously never be ignored that viruses are responsible for devastating diseases, it is clear that the more they are studied, the more possibilities they offer to us. They are now on the front line of the most revolutionizing techniques in several fields, providing advances that would not be possible without their existence. In this book there are presented studies that demonstrate the work developed using viruses in biotechnology. These studies were brought by experts that focus on the development and applications of many viruses in several fields, such as agriculture, the pharmaceutical industry, and medicine.
606   $aTechnology: general issues$2bicssc
610   $aAAV
610   $aadeno-associated virus
610   $aadeno-associated virus (AAV) vector
610   $aapple latent spherical virus vector
610   $aaspect ratio
610   $abacmid
610   $aBacteriophage
610   $abaculovirus
610   $abiocontrol
610   $abioreactor
610   $abreeding of grapevine
610   $acancer
610   $acancer gene therapy
610   $acancers
610   $acarotenoid biosynthesis
610   $achemokines
610   $achikungunya virus
610   $acircular RNA
610   $aclodronate
610   $acodon harmonization
610   $acodon optimization
610   $acomparative genomics
610   $aCOVID-19
610   $aCOVID-19 vaccines
610   $aCPMV
610   $aCRISPR
610   $aCRISPR-cas9
610   $aCRISPR/Cas systems
610   $aCRISPR/Cas9
610   $adiagnosis
610   $aDNA-based vaccines
610   $aenhancer
610   $aEscherichia coli
610   $aexpression vectors
610   $ageminivirus
610   $agene editing
610   $agene expression
610   $agene therapy
610   $agenome editing
610   $agenome stability
610   $agrapevine
610   $aheterologous expression
610   $ahydrothermal vent
610   $aHypnocyclicus thermotrophus
610   $aimmunization
610   $ainfectious bursal disease virus
610   $ainfectious diseases
610   $ainsect cells
610   $ajaagsiekte sheep retrovirus (JSRV)
610   $aLTR
610   $alytic cassette
610   $amacrophage
610   $ananotechnology
610   $aNewcastle disease virus
610   $aphage diversity
610   $aphages
610   $apig
610   $aplant genome engineering
610   $aplant virus
610   $aporcine epidemic diarrhea virus
610   $aprevention
610   $aprophage
610   $aprotein expression
610   $aPVX
610   $arecombinant Lactococcus lactis
610   $areduced generation time
610   $areverse genetics
610   $aRNA-based vaccines
610   $aSalmonella
610   $aSARS-CoV-2
610   $aself-replicating RNA vectors
610   $atheranostics
610   $aTMV
610   $aTn7
610   $atransduction
610   $atreatment
610   $avaccine
610   $avaccines
610   $avariant strain
610   $aviral resistance
610   $aviral vaccines
610   $aviral vector
610   $aviral vectors
610   $aviroid
610   $avirus elimination
610   $avirus-induced flowering
610   $avirus-induced gene silencing (VIGS)
610   $aviruses
610   $aVLP
610   $aVLPs
610   $aVNPs
615  7$aTechnology: general issues
700   $aVaranda$b Carla$4edt$01302211
702   $aMateratski$b Patrick$4edt
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702   $aMateratski$b Patrick$4oth
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996   $aThe Application of Viruses to Biotechnology$93026255
997   $aUNINA

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200 10$aPlant-Plant Allelopathic Interactions II $eLaboratory Bioassays for Water-Soluble Compounds with an Emphasis on Phenolic Acids /$fby Udo Blum
205   $a1st ed. 2014.
210  1$aCham :$cSpringer International Publishing :$cImprint: Springer,$d2014.
215   $a1 online resource (337 p.)
300   $aDescription based upon print version of record.
311   $a3-319-04731-0 
320   $aIncludes bibliographical references at the end of each chapters and indexes.
327   $a1 Background for Designing Laboratory Bioassays -- 2 Introduction to the Fundamentals of Laboratory Bioassays -- 3 Some Issues and Challenges When Designing Laboratory Bioassays -- 4 Hypothetical Standard Screening Bioassays -- 5 Effects, Modifiers and Modes of Action of Allelopathic Compounds Using Phenolic Acids as Model Compounds -- 6 Hypothetical Cause and Effect Bioassays -- 7 Laboratory Model Systems and Field Systems: Some Final Thoughts -- Author Index -- Subject Index.
330   $aIn the first volume the author suggested that we could improve our understanding of plant-plant allelopathic interactions in the field by making laboratory bioassays more holistic.  Reflections after the volume was published lead the author to conclude that a more detailed analysis of the factors making up laboratory bioassays was needed in the hope that such an analysis would provide clearer and more useful directions on how to design more holistic or more relevant laboratory bioassay systems.  The more holistic being a theoretical goal and the more relevant being a more pragmatic goal.  This volume has been written specifically for researchers and their graduate students who are interested in studying plant-plant allelopathic interactions.  The author hopes that this retrospective and at times critical analysis of laboratory bioassays will provide a foundation for better and more field-relevant laboratory designs in the future.  This volume has 7 chapters describing: 1. background for designing plant-plant allelopathic laboratory bioassays, 2. the fundamentals of laboratory bioassays, 3. the issues and challenges associated with designing more relevant laboratory bioassays, 4. a set of hypothetical standard screening laboratory bioassays, 5. the known effects of putative allelopathic compounds such as phenolic acids, the physicochemical and biotic factors that modify their effects, and their modes of action, 6. a set of standard hypothetical cause and effect laboratory bioassays, and 7. the differences between field systems and laboratory bioassay systems, ways to minimize the impacts of atypical factors in laboratory bioassays, and future directions.
606   $aBiotechnology
606   $aBotanical chemistry
606   $aPlant ecology
606   $aEnvironmental toxicology
606   $aBiotechnology$3https://scigraph.springernature.com/ontologies/product-market-codes/C12002
606   $aPlant Biochemistry$3https://scigraph.springernature.com/ontologies/product-market-codes/L14021
606   $aPlant Ecology$3https://scigraph.springernature.com/ontologies/product-market-codes/L19112
606   $aEcotoxicology$3https://scigraph.springernature.com/ontologies/product-market-codes/U25001
615  0$aBiotechnology.
615  0$aBotanical chemistry.
615  0$aPlant ecology.
615  0$aEnvironmental toxicology.
615 14$aBiotechnology.
615 24$aPlant Biochemistry.
615 24$aPlant Ecology.
615 24$aEcotoxicology.
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