Index of biophysics articles
This is a list of articles on biophysics.
0–9
A
- ACCN1
- ANO1
- AP2 adaptor complex
- Aaron Klug
- Acid-sensing ion channel
- Activating function
- Active transport
- Adolf Eugen Fick
- Afterdepolarization
- Aggregate modulus
- Aharon Katzir
- Alan Lloyd Hodgkin
- Alexander Rich
- Alexander van Oudenaarden
- Allan McLeod Cormack
- Alpha-3 beta-4 nicotinic receptor
- Alpha-4 beta-2 nicotinic receptor
- Alpha-7 nicotinic receptor
- Alpha helix
- Alwyn Jones (biophysicist)
- Amoeboid movement
- Andreas Mershin
- Andrew Huxley
- Animal locomotion
- Animal locomotion on the water surface
- Anita Goel
- Antiporter
- Aquaporin 2
- Aquaporin 3
- Aquaporin 4
- Archibald Hill
- Ariel Fernandez
- Arthropod exoskeleton
- Arthropod leg
- Avery Gilbert
B
- BEST2
- BK channel
- Bacterial outer membrane
- Balance (ability)
- Bat
- Bat wing development
- Bert Sakmann
- Bestrophin 1
- Biased random walk (biochemistry)
- Bioelectrochemical reactor
- Bioelectrochemistry
- Biofilm
- Biological material
- Biological membrane
- Biomechanics
- Biomechanics of sprint running
- Biophysical Society
- Biophysics
- Bird flight
- Bird migration
- Bisindolylmaleimide
- Bleb (cell biology)
- Boris Pavlovich Belousov
- Brian Matthews (biochemist)
- Britton Chance
- Brush border
- Bulk movement
C
- CACNA1G
- CACNA1H
- CACNA1I
- CACNA2D1
- CACNA2D2
- CACNB1
- CACNB2
- CACNB3
- CACNB4
- CACNG1
- CACNG2
- CACNG3
- CACNG4
- CD22
- CD33
- CHRNA10
- CHRNA2
- CHRNA3
- CHRNA4
- CHRNA5
- CHRNA6
- CHRNA7
- CHRNA9
- CHRNB1
- CHRNB2
- CHRNB3
- CHRNB4
- CHRND
- CHRNE
- CHRNG
- CLCA1
- CLCA2
- CLCA3
- CLCA4
- CLCC1
- CLCN1
- CLCN2
- CLCN3
- CLCN4
- CLCN5
- CLCN6
- CLCN7
- CLCNKA
- CLCNKB
- CLIC1
- CLIC2
- CLIC3
- CLIC4
- CLIC5
- CLIC6
- CLNS1A
- CLNS1B
- CNGB1
- Calcium-activated potassium channel
- Calcium-activated potassium channel subunit alpha-1
- Calcium 2-aminoethylphosphate
- Calcium channel
- Canadian Society for Biomechanics
- Cardiolipin
- Carlos Chagas Filho
- Carrier protein
- CatSper1
- CatSper2
- CatSper3
- CatSper4
- Cation channels of sperm
- Cav1.1
- Cav1.2
- Cav1.3
- Cav1.4
- Cav2.1
- Cell adhesion molecule
- Cell membrane
- Cellular component
- Channelome
- Channelomics
- Channelrhodopsin
- Charles Tanford
- Chemorepulsion
- Chloride channel
- Chloroplast membrane
- Cholesterol depletion
- Cholinergic receptor, nicotinic, alpha 1
- Chorioallantoic membrane
- Christian B. Anfinsen
- Cilium
- Climbing
- Cometabolism
- Comparative foot morphology
- Connexon
- Core (anatomy)
- Countercurrent multiplication
- Crenation
- Crista
- Cyclic nucleotide-gated channel alpha 1
- Cyclic nucleotide-gated channel alpha 2
- Cyclic nucleotide-gated channel alpha 3
- Cyclic nucleotide-gated channel alpha 4
- Cyclic nucleotide-gated ion channel
- Cyclic nucleotide gated channel beta 3
- Cys-loop receptors
- Cytolysis
D
- David Callaway
- David Cohen (physicist)
- David E. Goldman
- David J. Brenner
- David Keynes Hill
- David Mervyn Blow
- David S. Cafiso
- David States
- Davydov soliton
- Dendrosome
- Denny's paradox
- Depolarization
- Detlev Bronk
- Dopamine transporter
- Douglas Warrick
- Dušan Ristanović
- Dynamic similarity (Reynolds and Womersley numbers)
E
- Ecomechanics
- Efflux (microbiology)
- Egg white
- Elasticity of cell membranes
- Electrochemical gradient
- Electromethanogenesis
- Electrophysiology
- Electrotonic potential
- Elizabeth Rhoades
- Ena/Vasp homology proteins
- Endocytosis
- Endomembrane system
- Endoskeleton
- Enid MacRobbie
- Enzymatic biofuel cell
- Enzyme kinetics
- Ephraim Katzir
- Eric Kandel
- Erich Sackmann
- Erwin Neher
- Escheriosome
- Eva Nogales
- Excitatory amino-acid transporter
- Exoskeleton
- Extracellular field potential
- Extracellular polymeric substance
F
G
- G. N. Ramachandran
- G12/G13 alpha subunits
- GABAA receptor
- GABRA2
- GABRA3
- GABRA4
- GABRA5
- GABRA6
- GABRB1
- GABRB2
- GABRB3
- GABRD
- GABRE
- GABRG1
- GABRG2
- GABRG3
- GABRP
- GABRQ
- GABRR1
- GABRR2
- GABRR3
- GHK flux equation
- GLRA2
- GLRA3
- GLRA4
- GLRB
- GLUT1
- GLUT8
- GPCR oligomer
- GRIA1
- GRIA2
- GRIA3
- GRIA4
- GRIK1
- GRIK2
- GRIK3
- GRIK4
- GRIK5
- GRIN1
- GRIN2A
- GRIN2B
- GRIN2C
- GRIN2D
- GRIN3A
- GRIN3B
- GRINL1A
- GRINL1B
- G protein
- G protein-coupled inwardly-rectifying potassium channel
- G protein-coupled receptor
- G protein-gated ion channel
- Gamma-aminobutyric acid receptor subunit alpha-1
- Ganglion type nicotinic receptor
- Gating (electrophysiology)
- Geoffrey West
- Georg von Békésy
- George Karreman
- George V. Lauder
- Gilbert Stead
- Gliding motility
- Glycerophospholipid
- Glycine receptor, alpha 1
- Glycophosphatidylinositol
- Godfrey Hounsfield
- Gopinath Kartha
- Gq alpha subunit
- Gray's paradox
- Ground reaction force
- Gs alpha subunit
- Gunther O. Hofmann
H
- HCN1
- HCN2
- HCN3
- HCN4
- HCN channel
- HERG
- HTR3A
- HTR3B
- HTR3C
- HTR3D
- HTR3E
- HVCN1
- Hal Anger
- Hans Frauenfelder
- Haptotaxis
- Harold J. Morowitz
- Harry F. Noller
- Henri Atlan
- Hermann Joseph Muller
- Hermann von Helmholtz
- Heterotrimeric G protein
- Hill's muscle model
- Hille equation
- Hodgkin cycle
- Hodgkin–Huxley model
- Homeoviscous adaptation
- Homologous desensitization
- Hopanoids
- Howard Berg
- Hugh Herr
- Human leg
- Human skeletal changes due to bipedalism
- Hydrophobic mismatch
- Hydrostatic skeleton
- Hyperpolarization (biology)
I
- ITPR1
- ITPR2
- ITPR3
- Iatrogenic hypocholesterolemia
- Ichiji Tasaki
- IgSF CAM
- Inner membrane
- Inner mitochondrial membrane
- Insect wing
- Integral membrane protein
- Interbilayer forces in membrane fusion
- International Foot and Ankle Biomechanics Community (i-FAB)
- Intracellular membranes
- Invadopodia
- Inward-rectifier potassium ion channel
- Ion channel
- Ionotropic effect
J
- J. Murdoch Ritchie
- Jacques-Arsène d'Arsonval
- James D. Watson
- Jane S. Richardson
- Jeffry B. Skiba
- Jeremy C. Smith (scientist)
- Jerome Wolken
- Johan Paulsson
- John C. Taschner
- John Desmond Bernal
- John Heuser
- John Hopfield
- John Kendrew
- Journal of Applied Biomechanics
- Julia Goodfellow
K
- KCNA10
- KCNA2
- KCNA3
- KCNA4
- KCNA5
- KCNA6
- KCNA7
- KCNAB1
- KCNAB2
- KCNAB3
- KCNB1
- KCNB2
- KCNC1
- KCNC2
- KCNC3
- KCNC4
- KCND1
- KCNE1L
- KCNE2
- KCNE4
- KCNF1
- KCNG1
- KCNG2
- KCNG3
- KCNG4
- KCNH3
- KCNH4
- KCNH6
- KCNH7
- KCNH8
- KCNIP1
- KCNIP4
- KCNJ10
- KCNJ12
- KCNJ13
- KCNJ14
- KCNJ15
- KCNJ16
- KCNJ3
- KCNJ4
- KCNJ5
- KCNJ6
- KCNJ8
- KCNJ9
- KCNK1
- KCNK10
- KCNK12
- KCNK13
- KCNK15
- KCNK16
- KCNK17
- KCNK18
- KCNK2
- KCNK3
- KCNK4
- KCNK5
- KCNK6
- KCNK7
- KCNK9
- KCNMB1
- KCNMB2
- KCNMB3
- KCNMB4
- KCNN1
- KCNN2
- KCNN4
- KCNQ4
- KCNQ5
- KCNS1
- KCNS2
- KCNS3
- KCNT1
- KCNT2
- KCNV1
- KCNV2
- Kenneth Stewart Cole
- Kim Sung-Hou
- Kir2.1
- Kir2.6
- Kir6.2
- Kv1.1
- KvLQT1
- KvLQT2
- KvLQT3
L
- L-type calcium channel
- Lamellar structure
- Lamellipodium
- Lead (leg)
- Lecithin
- Lee Spetner
- Leslie Barnett
- Ligand-gated ion channel
- Light-gated ion channel
- Lignocellulosic biomass
- Limitations of animal running speed
- Linus Pauling
- Lipid-anchored protein
- Lipid bilayer
- Lipid bilayer characterization
- Lipid bilayer fusion
- Lipid bilayer mechanics
- Lipid bilayer phase behavior
- Lipid raft
- Liposome
- Liquid ordered phase
- List of biophysicists
- List of birds by flight speed
- List of jumping activities
- LocDB
- Locomotor activity
- Locomotor effects of shoes
- Luca Turin
- Lymphocyte homing receptor
M
- M1 protein
- M2 proton channel
- MHC class I
- Magnesium transporter
- Magnetoception
- Magnetosome
- Magnetospirillum
- Magnetotactic bacteria
- Magnetotaxis
- Manfred Eigen
- Marcelo Osvaldo Magnasco
- Marche a petit pas
- Mario Ageno
- Martin Gruebele
- Maurice Wilkins
- Max Delbrück
- Max Perutz
- Mechanics of human sexuality
- Mechanome
- Mechanosensitive channels
- Mechanotaxis
- Membrane biology
- Membrane channel
- Membrane contact site
- Membrane curvature
- Membrane fluidity
- Membrane lipids
- Membrane nanotube
- Membrane potential
- Membrane protein
- Membrane topology
- Membrane transport
- Membranome
- Mesaxon
- Mesosome
- Metachronal rhythm
- Methylhopane
- Microbial ecology
- Microbial fuel cell
- Microsome
- Model lipid bilayer
- Moens–Korteweg equation
- Mohammad-Nabi Sarbolouki
- Molecular motor
- Monoamine transporter
- Motility
- Motor protein
- Mucous membrane
- Mucous membrane of the soft palate
- Muscular hydrostat
- Muscular layer
- Muscularis mucosae
- Myelin-associated glycoprotein
- Myelin sheath gap
- Myofilament
- Mária Telkes
N
O
- Optical tweezers
- Oreste Piro
- Origin of avian flight
- Osmoregulation
- Osmotic pressure
- Outer mitochondrial membrane
- Outline of biophysics
- Overhead throwing motion
P
- P-type ATPase
- P-type calcium channel
- P2RX1
- P2RX2
- P2RX3
- P2RX4
- P2RX5
- P2RX6
- P2RX7
- P2X purinoreceptor
- P300-CBP coactivator family
- PF-4840154
- PKD1
- PSORT
- PSORTdb
- PTS1R
- Parkinsonian gait
- Passive transport
- Paul Lauterbur
- Paulien Hogeweg
- Peptide transporter 1
- Peptidoglycan
- Peroxisomal targeting signal
- Perylene
- Peter Mansfield
- Petr Paucek
- Phosphatidylethanolamine
- Phosphatidylglycerol
- Phosphatidylinositol
- Phosphatidylserine
- Physics of skiing
- Pink algae
- Plasma membrane monoamine transporter
- Plasmolysis
- Platelet-derived growth factor receptor
- Pleuroperitoneal
- Podosome
- Polar membrane
- Porosome
- Potassium channel
- Prenylation
- Preprohormone
- Pressure-volume curves
- Primary active transport
- Protein Analysis Subcellular Localization Prediction
- Protein targeting
- Protein–lipid interaction
- Protomer
- Protoplast
- Pseudopeptidoglycan
- Pseudopodia
- Pterygium
R
- R-type calcium channel
- ROMK
- RYR1
- RYR3
- Radial spoke
- Receptor (biochemistry)
- Reinhart Heinrich
- Reversal potential
- Richard Ernest Kronauer
- Robert Corey
- Robert G. Shulman
- Robert Haynes
- Robley C. Williams
- Roger Wartell
- Roland Benz
- Role of skin in locomotion
- Rosalind Franklin
- Rosalyn Sussman Yalow
- Rotating locomotion in living systems
- Rudolf Podgornik
- Ryanodine receptor 2
S
- S-layer
- SCN10A
- SCN1B
- SCN2B
- SCN3A
- SCN3B
- SCN4B
- SCN7A
- SCN8A
- SCNN1A
- SCNN1B
- SCNN1D
- SCNN1G
- SIGLEC
- SK3
- SK channel
- Saffman–Delbrück model
- Sammy Lee (scientist)
- Sarcolemma
- Sarcomere
- SecY protein
- Secondary active transport
- Secretory pathway
- Semipermeable membrane
- Sergei Kovalev
- Serotonin transporter
- Serous membrane
- Sessility (zoology)
- Shaker gene
- Sialoadhesin
- Sidney Altman
- Signal patch
- Signal peptide
- Signal peptide peptidase
- Signal recognition particle receptor
- Silent synapse
- Simon Shnoll
- Simtk-opensim
- SkQ
- Small-conductance mechanosensitive channel
- Sodium channel
- Soft tissue
- Soluble cell adhesion molecules
- Solute pumping
- Sorting and assembly machinery
- Sphingomyelin
- Spinal locomotion
- Sports biomechanics
- Steady state (biochemistry)
- Stephen D. Levene
- Stretch-activated ion channel
- Stroma (fluid)
- Structural biology
- Structural genomics
- Structure validation
- Stuart Kauffman
- Submucosa
- Subserosa
- Synthetic ion channels
T
- T-tubule
- T-type calcium channel
- TPCN1
- TPCN2
- TRPA (channel)
- TRPC
- TRPC1
- TRPC2
- TRPC3
- TRPC4AP
- TRPC5
- TRPC6
- TRPC7
- TRPM
- TRPM1
- TRPM2
- TRPM3
- TRPM4
- TRPM5
- TRPM6
- TRPM7
- TRPM8
- TRPML
- TRPN
- TRPP
- TRPP3
- TRPV
- TRPV1
- TRPV2
- TRPV3
- TRPV4
- TRPV5
- TRPV6
- Talin protein
- Tandem pore domain potassium channel
- Tatyana Sapunova
- Tetraspanin
- Theories of general anaesthetic action
- Thomas A. Steitz
- Thomas Gold
- Thylakoid
- Total internal reflection fluorescence microscope
- Tradeoffs for locomotion in air and water
- Transepithelial potential difference
- Transient receptor potential cation channel, member A1
- Transient receptor potential channel
- Transient receptor potential channel-interacting protein database
- Translocon
- Transmembrane channels
- Treadmilling
- Turgor pressure
- Twin-arginine translocation pathway
- Two-pore channel
V
- VCAM-1
- VDAC1
- VDAC2
- VDAC3
- V formation
- Venkatraman Ramakrishnan
- Vertical clinging and leaping
- Vesicle (biology and chemistry)
- Vestibulo emotional reflex
- Voltage-dependent anion channel
- Voltage-dependent calcium channel
- Voltage-gated ion channel
- Voltage-gated potassium channel
- Voltage-gated potassium channel database
- Voltage-gated proton channel
Z
gollark: I mean, it's not like *all* the subjects died.
gollark: You *can*, but loading all the information - much of it conflicting - into your brain *has* been known to lead to a few moderately problematic side effects.
gollark: Now, while modern mindstate execution is fully deterministic, people aren't perfect judges of the "best" thing and there's some noise, so you probably want to use comparison counting sort or something.
gollark: You can either read aesthetic appreciation data out of their mindstates and rank that, or just use one per *comparison* instead.
gollark: We use a few countable infinities of them as workers, although some need the existential horror neural pathways damped a lot.
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