A01=Hernan Garcia

A01=Jané Kondev

A01=Julie Theriot

A01=Rob Phillips

Actin Filaments

activator

active transport

ADP Molecule

Age Group_Uncategorized

allostery

angle variable

antibiotic resistance

ATP

ATP Concentration

ATP Hydrolysis

ATP Synthase

Author_Hernan Garcia

Author_Jané Kondev

Author_Julie Theriot

Author_Rob Phillips

automatic-update

bacteriophage

beam theory

Binding Sites

biochemistry

biofunctionalized cantilever

biological distance

biological electricity

biologyical dynamics

biophysics

Boltzmann distribution

Brownian motion

c. elegans

cable equation

cartoon

Category1=Non-Fiction

Category=PSF

cell crowding

cell cylce

cell dynamics

cell structure

central dogma

centrifugation

charge distribution

chemotaxis

chromosome

cilia

clock

collinearity

concentration gradient

cooperativity

COP=United States

Cytoskeletal Filament

cytoskeleton

Delivery_Delivery within 10-20 working days

depletion force

depolarization wave

diffusion

DNA Looping

DNA Mechanic

DNA Molecule

DNA packing

DNA virus

dynamic instability

e. coli

electrochemical gradient

electrostatic potential

electrostatistics

energetics

energy

entropy

eq_isMigrated=2

eq_non-fiction

eq_science

equilibrium accessibility

equilibrium polymer

estimation

excluded volume

extension curve

FCS

Fick's Law

flagella

fluid dynamics

fluid velocity

flux

Force Extension Curve

FRAP

Frap Experiment

Gaussian curvature

gene expression

gene network

genetic map

genetics

genomics

Gibbs distribution

height function

hemoglobin

Hill function

Hodgkin-Huxley model

homology

Hp Model

hydrodynamics

hydrolysis

ideal gas

ion channel

kinetics

Lac Operon

Lac Repressor

Language_English

lattice model

Law of Mass Action

leukocyte rolling

ligand

Ligand Receptor Binding

lipid bilayer

low Reynolds number

macromolecular crowding

macromolecular delay

macromolecule

Mechanosensitive Channel

membrane potential

membrane protein

membrane tension

Michaelis-Menten

microstate

model building

model organism

model system

modeling

molecular biology

molecular motor

motor protein

MscL

muscle contraction

MWC Model

Navier-Stokes Equation

negative feedback

Nernst equation

neuroscience

operon

Optical Trap

Optical Tweezers

order-of-magnitude biology

oscillator

osmotic pressure

PA=Available

particle resevoir

Partition Function

passive transport

PCR

PDB file

permeability

persistance length

Persistence Length

pH

phosphorylation

phylogeny

Physical Biology

Poisson-Boltzmann

polymerase

polymerization

polymerization ratchet

positive feedback

Price_€50 to €100

probability

promoter

protein folding

protein recruitment

protein structure

proteomics

PS=Active

quadratic function

quantitative biology

quantitative data

quantitative modeling

random walk

Random Walk Model

rate equation

reaction-diffusion model

receptor

receptor binding

repressor

RNA Polymerase

salt solution

scale

sequence alignment

Smoluchowski Equation

sodium channel

softlaunch

spectroscopy

state variable

statistical mechanics

steady-state

stokes drag

Stokes flow

switch region

thickness function

time

time scale

tissue

translocation

translocation ratchet

two-state model

two-state system

vesicle

viral evolution

virus

voltage-gated ion channel

water

Physical Biology of the Cell

Name: Physical Biology of the Cell
Brand: Taylor & Francis Inc
SKU: 9780815344506
Price: 104.99 EUR
Availability: InStock

★★★★★

English

By (author): Hernan Garcia Jané Kondev Julie Theriot Rob Phillips

Physical Biology of the Cell is a textbook for a first course in physical biology or biophysics for undergraduate or graduate students. It maps the huge and complex landscape of cell and molecular biology from the distinct perspective of physical biology. As a key organizing principle, the proximity of topics is based on the physical concepts that unite a given set of biological phenomena. Herein lies the central premise: that the appropriate application of a few fundamental physical models can serve as the foundation of whole bodies of quantitative biological intuition, useful across a wide range of biological problems. The Second Edition features full-color illustrations throughout, two new chapters, a significantly expanded set of end-of-chapter problems, and is available in a variety of e-book formats.

€104.99

Quantity

A01=Hernan GarciaA01=Jané KondevA01=Julie TheriotA01=Rob PhillipsActin Filamentsactivatoractive transportADP MoleculeAge Group_Uncategorizedallosteryangle variableantibiotic resistanceATPATP ConcentrationATP HydrolysisATP SynthaseAuthor_Hernan GarciaAuthor_Jané KondevAuthor_Julie TheriotAuthor_Rob Phillipsautomatic-updatebacteriophagebeam theoryBinding Sitesbiochemistrybiofunctionalized cantileverbiological distancebiological electricitybiologyical dynamicsbiophysicsBoltzmann distributionBrownian motionc. eleganscable equationcartoonCategory1=Non-FictionCategory=PSFcell crowdingcell cylcecell dynamicscell structurecentral dogmacentrifugationcharge distributionchemotaxischromosomeciliaclockcollinearityconcentration gradientcooperativityCOP=United StatesCytoskeletal FilamentcytoskeletonDelivery_Delivery within 10-20 working daysdepletion forcedepolarization wavediffusionDNA LoopingDNA MechanicDNA MoleculeDNA packingDNA virusdynamic instabilitye. colielectrochemical gradientelectrostatic potentialelectrostatisticsenergeticsenergyentropyeq_isMigrated=2eq_non-fictioneq_scienceequilibrium accessibilityequilibrium polymerestimationexcluded volumeextension curveFCSFick's Lawflagellafluid dynamicsfluid velocityfluxForce Extension CurveFRAPFrap ExperimentGaussian curvaturegene expressiongene networkgenetic mapgeneticsgenomicsGibbs distributionheight functionhemoglobinHill functionHodgkin-Huxley modelhomologyHp Modelhydrodynamicshydrolysisideal gasion channelkineticsLac OperonLac RepressorLanguage_Englishlattice modelLaw of Mass Actionleukocyte rollingligandLigand Receptor Bindinglipid bilayerlow Reynolds numbermacromolecular crowdingmacromolecular delaymacromoleculeMechanosensitive Channelmembrane potentialmembrane proteinmembrane tensionMichaelis-Mentenmicrostatemodel buildingmodel organismmodel systemmodelingmolecular biologymolecular motormotor proteinMscLmuscle contractionMWC ModelNavier-Stokes Equationnegative feedbackNernst equationneuroscienceoperonOptical TrapOptical Tweezersorder-of-magnitude biologyoscillatorosmotic pressurePA=Availableparticle resevoirPartition Functionpassive transportPCRPDB filepermeabilitypersistance lengthPersistence LengthpHphosphorylationphylogenyPhysical BiologyPoisson-Boltzmannpolymerasepolymerizationpolymerization ratchetpositive feedbackPrice_€50 to €100probabilitypromoterprotein foldingprotein recruitmentprotein structureproteomicsPS=Activequadratic functionquantitative biologyquantitative dataquantitative modelingrandom walkRandom Walk Modelrate equationreaction-diffusion modelreceptorreceptor bindingrepressorRNA Polymerasesalt solutionscalesequence alignmentSmoluchowski Equationsodium channelsoftlaunchspectroscopystate variablestatistical mechanicssteady-statestokes dragStokes flowswitch regionthickness functiontimetime scaletissuetranslocationtranslocation ratchettwo-state modeltwo-state systemvesicleviral evolutionvirusvoltage-gated ion channelwater

Delivery/Collection within 10-20 working days

Product Details

Weight: 3249g
Dimensions: 219 x 276mm
Publication Date: 29 Oct 2012
Publisher: Taylor & Francis Inc
Publication City/Country: US
Language: English
ISBN13: 9780815344506

About Hernan GarciaJané KondevJulie TheriotRob Phillips

Rob Phillips is the Fred and Nancy Morris Professor of Biophysics and Biology at the California Institute of Technology. He received a PhD in Physics from Washington University in St. Louis.

Jane Kondev is a Professor of Physics in the Graduate Program in Quantitative Biology at Brandeis University. He received his Physics BS degree from the University of Belgrade, and his PhD from Cornell University.

Julie Theriot is a Professor of Biochemistry and of Microbiology and Immunology at the Stanford University School of Medicine. She received concurrent BS degrees in Physics and Biology from the Massachusetts Institute of Technology, and a PhD in Cell Biology from the University of California at San Francisco.

Hernan G. Garcia is an Associate Research Fellow at Princeton University. He received a BS in Physics from the University of Buenos Aires and a PhD in Physics from the California Institute of Technology.

Physical Biology of the Cell

Product Details

About Hernan GarciaJané KondevJulie TheriotRob Phillips

Customer Reviews

Added to your cart: