FRINK Linked Data Fragments server

Matches in Ubergraph for { <https://frink.apps.renci.org/.well-known/genid/Ba8e9d6e8c2244b7154f9e1d0c465424c> ?p ?o ?g. }

• Ba8e9d6e8c2244b7154f9e1d0c465424c hasDbXref "PMID:11785756" @default.
• Ba8e9d6e8c2244b7154f9e1d0c465424c type Axiom @default.
• Ba8e9d6e8c2244b7154f9e1d0c465424c annotatedProperty IAO_0000115 @default.
• Ba8e9d6e8c2244b7154f9e1d0c465424c annotatedSource MI_0065 @default.
• Ba8e9d6e8c2244b7154f9e1d0c465424c annotatedTarget "Isothermal titration calorimetry (ITC) measures directly the energy associated with a chemical reaction triggered by the mixing of two components. A typical ITC experiment is carried out by the stepwise addition of one of the reactants (~10-6 L per injection) into the reaction cell (~1mL) containing the second reactant. The chemical reaction occurring after each injection either releases or absorbs heat (qi) proportional to the amount of ligand that binds to the protein with a characteristic binding enthalpy (DH). As modern ITC instruments operate on the heat compensation principle, the instrumental response (measured signal) is the amount of power (microcalories per second) necessary to maintain constant the temperature difference between the reaction and the reference cells. Because the amount of uncomplexed protein available progressively decreases after each successive injection, the magnitude of the peaks becomes progressively smaller until complete saturation is achieved. The difference between the concentration of bound ligand in the ith and (i-1)th injections depends on the binding constant Ka and the total ligand injected. The calculations depend on the binding model (number of substrates). Analysis of the data yields DH and DG = -RTlnKa. The entropy change is obtained by using the standard thermodynamic expression DG = DH-TDS." @default.