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200 10$aGenerating evidence for genomic diagnostic test development$b[electronic resource] $eworkshop Summary /$fTheresa Wizemann and Adam C. Berger, rapporteurs ; Roundtable on translating Genomic-Based Research for Health, Board on Health Sciences Policy, Institute of Medicine of the National Academies
210   $aWashington, D.C. $cNational Academies Press$d2011
215   $a1 online resource (100 p.)
300   $aDescription based upon print version of record.
311   $a0-309-21104-2 
320   $aIncludes bibliographical references.
327   $a""Front Matter""; ""Reviewers""; ""Acknowledgments""; ""Contents""; ""Tables, Figures, and Boxes""; ""Abbreviations and Acronyms""; ""1 Introduction""; ""2 Stakeholder Perspectives on Evidence""; ""3 Approaches to Evidence Generation""; ""4 Overcoming Barriers for Evidence Generation""; ""5 Considerations Moving Forward""; ""6 Final Remarks""; ""References""; ""Appendix A: Workshop Agenda""; ""Appendix B: Speaker Biographical Sketches""; ""Appendix C: Registered Attendees""
330   $a"Ten years after the sequencing of the human genome, scientists have developed genetic tests that can predict a person's response to certain drugs, estimate the risk of developing Alzheimer's disease, and make other predictions based on known links between genes and diseases. However, genetic tests have yet to become a routine part of medical care, in part because there is not enough evidence to show they help improve patients' health.The Institute of Medicine (IOM) held a workshop to explore how researchers can gather better evidence more efficiently on the clinical utility of genetic tests. Generating Evidence for Genomic Diagnostic Test Development compares the evidence that is required for decisions regarding clearance, use, and reimbursement, to the evidence that is currently generated. The report also addresses innovative and efficient ways to generate high-quality evidence, as well as barriers to generating this evidence. Generating Evidence for Genomic Diagnostic Test Development contains information that will be of great value to regulators and policymakers, payers, health-care providers, researchers, funders, and evidence-based review groups."--Publisher's description.
606   $aGenomics
606   $aDiagnosis
606   $aGene mapping
615  0$aGenomics.
615  0$aDiagnosis.
615  0$aGene mapping.
676   $a616.0420027
701   $aWizemann$b Theresa M$0890630
701   $aBerger$b Adam C$01120088
712 02$aInstitute of Medicine (U.S.).$bRoundtable on Translating Genomic-Based Research for Health.
712 02$aInstitute of Medicine (U.S.).$bBoard on Health Sciences Policy.
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996   $aGenerating evidence for genomic diagnostic test development$93817256
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200 00$aLocal Investigation of Single Magnetic Molecules with Scanning Tunneling Microscopy
210   $cKIT Scientific Publishing$d2018
215   $a1 online resource (II, 128 p. p.)
225 1 $aExperimental Condensed Matter Physics / Karlsruher Institut für Technologie, Physikalisches Institut
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330   $aWe worked on different magnetic molecules containing 3d and 4f magnetic centers. Their growth on metallic surfaces, topographies, spin states, magnetic properties and electron transport were locally investigated by using scanning tunneling microscopy (STM) at temperatures down to 30mK. The main achievement of this dissertation reveals the abrupt switching of crystal fields during formation of molecular contacts.
606   $aPhysics$2bicssc
610   $aeinzelnes magnetisches Moleku?l
610   $ainelastic excitation
610   $amolecular contact
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610   $ascanning tunneling microscopy
610   $asingle magnetic molecule
610   $aspin state
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700   $aChen$b Jinjie$4auth$01296315
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