Default Theme

Systems Biology [electronic resource] : Definitions and Perspectives / edited by Lila Alberghina, H.V. Westerhoff.

Call Number	570.285
Title	Systems Biology Definitions and Perspectives / edited by Lila Alberghina, H.V. Westerhoff.
Physical Description	XVII, 408 p. online resource.
Series	Topics in Current Genetics, 1610-2096 ; 13
Contents	Systems Biology of Apoptosis -- Mathematical Modeling of the Wnt-Pathway -- Modeling Signaling Pathways – A Yeast Approach -- Mechanistic and Modular Approaches to Modeling and Inference of Cellular Regulatory Networks -- Scientific and Technical Challenges for Systems Biology -- Integration of Metabolic and Signaling Networks -- From Isolation to Integration, a Systems Biology Approach for Building the Silicon Cell -- What’s Systems Biology: From Genes to Function and Back -- Systems Biology: Recent Developments and New Trends -- A Modular Systems Biology Analysis of the Cell Cycle Entrance into S Phase -- Metabolic Control Analysis -- Mesoscopic Kinetics and its Applications in Protein Synthesis -- E. coli Glycolysis -- Kinetic Modeling of the E. coli Metabolism -- No Music without Melody: How to Understand Biochemical Systems by Understanding Their Dynamics -- Systems Biology of the Yeast Cell Cycle Engine -- Quantification of in vivo Molecular Fluxes: A Key Methodology for Metabolic Systems Biology.-Modeling the E. coli cell: The Need for Computing, Cooperation, and Consortia.
Summary	For life to be understood and disease to become manageable, the wealth of postgenomic data now needs to be made dynamic. This development requires systems biology, integrating computational models for cells and organisms in health and disease; quantitative experiments (high-throughput, genome-wide, living cell, in silico); and new concepts and principles concerning interactions. This book defines the new field of systems biology and discusses the most efficient experimental and computational strategies. The benefits for industry, such as the new network-based drug-target design validation, and testing, are also presented.
Added Author	Alberghina, Lila. editor. Westerhoff, H.V. editor. SpringerLink (Online service)
Subject	LIFE SCIENCES. BIOCHEMISTRY. BIOINFORMATICS. CELL BIOLOGY. COMPUTATIONAL BIOLOGY. Life Sciences. Computer Appl. in Life Sciences. Cell Biology. Bioinformatics. Biochemistry, general.
Multimedia	http://dx.doi.org/10.1007/b95175

Libraries with this item

950	Biomedical and Life Sciences (Springer-11642)

Total Ratings: 0

Copies
MARC Record
Reviews
Details


No records found to display.

03555nam a22005655i 4500

001

vtls001568848

003

VRT

005

20170831185200.0

007

cr nn 008mamaa

008

170831s2005 gw | s |||| 0|eng d

020

$a 9783540314530 $9 978-3-540-31453-0

024

$a 10.1007/b95175 $2 doi

035

$a (DE-He213)978-3-540-31453-0

039

$y 201708311852 $z santha

050

$a QH324.2-324.25

072

$a PS $2 bicssc

072

$a UB $2 bicssc

072

$a SCI086000 $2 bisacsh

072

$a COM018000 $2 bisacsh

082

$a 570.285 $2 23

245

$a Systems Biology $h [electronic resource] : $b Definitions and Perspectives / $c edited by Lila Alberghina, H.V. Westerhoff.

264

$a Berlin, Heidelberg : $b Springer Berlin Heidelberg, $c 2005.

300

$a XVII, 408 p. $b online resource.

336

$a text $b txt $2 rdacontent

337

$a computer $b c $2 rdamedia

338

$a online resource $b cr $2 rdacarrier

347

$a text file $b PDF $2 rda

490

$a Topics in Current Genetics, $x 1610-2096 ; $v 13

505

$a Systems Biology of Apoptosis -- Mathematical Modeling of the Wnt-Pathway -- Modeling Signaling Pathways – A Yeast Approach -- Mechanistic and Modular Approaches to Modeling and Inference of Cellular Regulatory Networks -- Scientific and Technical Challenges for Systems Biology -- Integration of Metabolic and Signaling Networks -- From Isolation to Integration, a Systems Biology Approach for Building the Silicon Cell -- What’s Systems Biology: From Genes to Function and Back -- Systems Biology: Recent Developments and New Trends -- A Modular Systems Biology Analysis of the Cell Cycle Entrance into S Phase -- Metabolic Control Analysis -- Mesoscopic Kinetics and its Applications in Protein Synthesis -- E. coli Glycolysis -- Kinetic Modeling of the E. coli Metabolism -- No Music without Melody: How to Understand Biochemical Systems by Understanding Their Dynamics -- Systems Biology of the Yeast Cell Cycle Engine -- Quantification of in vivo Molecular Fluxes: A Key Methodology for Metabolic Systems Biology.-Modeling the E. coli cell: The Need for Computing, Cooperation, and Consortia.

520

$a For life to be understood and disease to become manageable, the wealth of postgenomic data now needs to be made dynamic. This development requires systems biology, integrating computational models for cells and organisms in health and disease; quantitative experiments (high-throughput, genome-wide, living cell, in silico); and new concepts and principles concerning interactions. This book defines the new field of systems biology and discusses the most efficient experimental and computational strategies. The benefits for industry, such as the new network-based drug-target design validation, and testing, are also presented.

650

$a LIFE SCIENCES.

650

$a BIOCHEMISTRY.

650

$a BIOINFORMATICS.

650

$a CELL BIOLOGY.

650

$a COMPUTATIONAL BIOLOGY.

650

$a Life Sciences.

650

$a Computer Appl. in Life Sciences.

650

$a Cell Biology.

650

$a Bioinformatics.

650

$a Biochemistry, general.

700

$a Alberghina, Lila. $e editor.

700

$a Westerhoff, H.V. $e editor.

710

$a SpringerLink (Online service)

773

$t Springer eBooks

776

$i Printed edition: $z 9783540229681

830

$a Topics in Current Genetics, $x 1610-2096 ; $v 13

856

$u http://dx.doi.org/10.1007/b95175

912

$a ZDB-2-SBL

950

$a Biomedical and Life Sciences (Springer-11642)

999

$a VIRTUA

No Reviews to Display

Summary	For life to be understood and disease to become manageable, the wealth of postgenomic data now needs to be made dynamic. This development requires systems biology, integrating computational models for cells and organisms in health and disease; quantitative experiments (high-throughput, genome-wide, living cell, in silico); and new concepts and principles concerning interactions. This book defines the new field of systems biology and discusses the most efficient experimental and computational strategies. The benefits for industry, such as the new network-based drug-target design validation, and testing, are also presented.
Contents	Systems Biology of Apoptosis -- Mathematical Modeling of the Wnt-Pathway -- Modeling Signaling Pathways – A Yeast Approach -- Mechanistic and Modular Approaches to Modeling and Inference of Cellular Regulatory Networks -- Scientific and Technical Challenges for Systems Biology -- Integration of Metabolic and Signaling Networks -- From Isolation to Integration, a Systems Biology Approach for Building the Silicon Cell -- What’s Systems Biology: From Genes to Function and Back -- Systems Biology: Recent Developments and New Trends -- A Modular Systems Biology Analysis of the Cell Cycle Entrance into S Phase -- Metabolic Control Analysis -- Mesoscopic Kinetics and its Applications in Protein Synthesis -- E. coli Glycolysis -- Kinetic Modeling of the E. coli Metabolism -- No Music without Melody: How to Understand Biochemical Systems by Understanding Their Dynamics -- Systems Biology of the Yeast Cell Cycle Engine -- Quantification of in vivo Molecular Fluxes: A Key Methodology for Metabolic Systems Biology.-Modeling the E. coli cell: The Need for Computing, Cooperation, and Consortia.
Subject	LIFE SCIENCES. BIOCHEMISTRY. BIOINFORMATICS. CELL BIOLOGY. COMPUTATIONAL BIOLOGY. Life Sciences. Computer Appl. in Life Sciences. Cell Biology. Bioinformatics. Biochemistry, general.
Multimedia	http://dx.doi.org/10.1007/b95175