Michaelis-Menten mechanism reconsidered: implications of fractal kinetics.
about
Function of metabolic and organelle networks in crowded and organized mediaA general model for binary cell fate decision gene circuits with degeneracy: indeterminacy and switch behavior in the absence of cooperativityMathematical modeling and validation of the ergosterol pathway in Saccharomyces cerevisiaeCharacterizability of metabolic pathway systems from time series dataS100A4 and its role in metastasis – computational integration of data on biological networks.Nonlinear regulation enhances the phenotypic expression of trans-acting genetic polymorphismsImmobilization of lambda exonuclease onto polymer micropillar arrays for the solid-phase digestion of dsDNAsInput-output relations in biological systems: measurement, information and the Hill equation.Predicting pancreas cell fate decisions and reprogramming with a hierarchical multi-attractor model.Steady-state global optimization of metabolic non-linear dynamic models through recasting into power-law canonical models.Constructing stochastic models from deterministic process equations by propensity adjustment.Genomics, complexity and drug discovery: insights from Boolean network models of cellular regulation.150 years of the mass action law.Statistical epistasis is a generic feature of gene regulatory networksReflections on the theory of "silver bullet" octreotide tracers: implications for ligand-receptor interactions in the age of peptides, heterodimers, receptor mosaics, truncated receptors, and multifractal analysis.Computational modeling of mitochondrial function.A biological interpretation of transient anomalous subdiffusion. II. Reaction kineticsAdvanced pharmacokinetic models based on organ clearance, circulatory, and fractal concepts.Fractal-like kinetics of intracellular enzymatic reactions: a chemical framework of endotoxin tolerance and a possible non-specific contribution of macromolecular crowding to cross-tolerance.Mathematical formalisms based on approximated kinetic representations for modeling genetic and metabolic pathways.Kinetic modeling of antibiotic adsorption onto different nanomaterials using the Brouers-Sotolongo fractal equation.The best models of metabolism.Monte carlo simulations of enzyme reactions in two dimensions: fractal kinetics and spatial segregation.Positive receptor feedback during lineage commitment can generate ultrasensitivity to ligand and confer robustness to a bistable switch.Validation of fractal-like kinetic models by time-resolved binding kinetics of dansylamide and carbonic anhydrase in crowded media.Rate constants for the first two chemical steps of eumelanogenesis.Reaction-diffusion with stochastic decay rates.Dynamic simulation of an in vitro multi-enzyme system.Introduction and General AspectsApplication of the Multistep Generalized Differential Transform Method to Solve a Time-Fractional Enzyme KineticsBiochemical Systems Theory: A Review
P2860
Q28080644-F4802B65-1730-4CDE-8B8F-1441FFE8F405Q28478193-1BC918A3-E229-4C67-B077-89DB31E5DE33Q28478408-3E2F27B1-AD16-4686-93B2-9A7D1157AC46Q28678879-AD924E97-445E-4220-8F50-90BCBB88DCDDQ30977149-8EF2A629-E1CA-44D7-92B0-B6E8762FB339Q33291673-7ED73900-DF28-4463-A164-C0A9AD610958Q33598857-446A6E6E-C357-427C-B017-8226F5571AC3Q33640919-A998A10C-BE1F-4B83-BB28-2C6BFC295DC4Q33851580-50D74822-1EFC-4888-B201-030EA2FFB76AQ34002893-557C58C3-C3BE-4026-89A2-7B30DC8BA891Q34069968-C6E6EFFA-8A23-4A23-847D-352EF71192E8Q34355237-6C83D3BC-23BD-4015-A080-E9E3C9757FE9Q35539889-6AC5E391-3728-49A1-9740-A459D6107CC9Q35598444-A177C0FE-96FF-48D2-BD55-AAA46AFE8207Q35650633-7FF5CC22-EBAC-4269-A29F-12EB2747EA9DQ35953224-58F60198-353E-43A8-89D4-B146B3CE4DEBQ36344977-44E64044-1129-4C80-A069-F311632C0975Q36956680-C1E43B0B-E622-4A2C-996D-E26AC80857ACQ37361507-EE2F4F57-9B48-4DFF-A860-5A0057DE7205Q37853843-32D1E08B-2DAE-4DE0-B792-48AE16D78044Q39121049-2C2F3FEC-0681-4426-AD63-709C90C5B0FAQ39330274-6E0E6F25-BC1F-4A1E-BA83-5F6DFA61D6C5Q40214745-502B101E-674F-45C7-9A73-A706E450A5E6Q40896161-BA32D081-2CFB-4100-83D5-4A1ECF8FCC80Q42732966-D03F6569-DD53-4C22-BB39-E41246BA1A09Q44570208-1FBBAF58-C351-465F-87D4-22E8490F0871Q47768534-E19006A6-9994-446B-8709-E25AFA566879Q54448145-DF9B631E-B058-4017-B04D-82CD616EB1CFQ57013473-090B1A93-5E79-4306-BDDB-F01348621DDDQ58921670-BD00D035-C9B2-4629-90E7-30007BDE1C01Q59000297-4D6910FB-FB90-4E3F-92F5-9AC6CE70B1AA
P2860
Michaelis-Menten mechanism reconsidered: implications of fractal kinetics.
description
1995 nî lūn-bûn
@nan
1995 թուականի Սեպտեմբերին հրատարակուած գիտական յօդուած
@hyw
1995 թվականի սեպտեմբերին հրատարակված գիտական հոդված
@hy
1995年の論文
@ja
1995年論文
@yue
1995年論文
@zh-hant
1995年論文
@zh-hk
1995年論文
@zh-mo
1995年論文
@zh-tw
1995年论文
@wuu
name
Michaelis-Menten mechanism reconsidered: implications of fractal kinetics.
@ast
Michaelis-Menten mechanism reconsidered: implications of fractal kinetics.
@en
Michaelis-Menten mechanism reconsidered: implications of fractal kinetics.
@nl
type
label
Michaelis-Menten mechanism reconsidered: implications of fractal kinetics.
@ast
Michaelis-Menten mechanism reconsidered: implications of fractal kinetics.
@en
Michaelis-Menten mechanism reconsidered: implications of fractal kinetics.
@nl
prefLabel
Michaelis-Menten mechanism reconsidered: implications of fractal kinetics.
@ast
Michaelis-Menten mechanism reconsidered: implications of fractal kinetics.
@en
Michaelis-Menten mechanism reconsidered: implications of fractal kinetics.
@nl
P356
P1476
Michaelis-Menten mechanism reconsidered: implications of fractal kinetics.
@en
P2093
Savageau MA
P304
P356
10.1006/JTBI.1995.0181
P407
P577
1995-09-01T00:00:00Z