Abstract: Disclosed is a capillary mixer for mixing first and second reactant solutions to form a mixed solution prior to delivering the mixed solution to an ion source of a mass spectrometer.

Abstract: The present invention provides a method and apparatus for detecting the noncovalent binding of a potential ligand (such as a drug candidate) to a target, e.g. a biochemical macromolecule such as a protein. The method is based on the Taylor dispersion of an initially sharp boundary between a carrier solution, and an analyte solution that contains the potential ligand(s) and the target. Dispersion profiles of one or more potential ligands are monitored by mass spectrometry at the exit of the laminar flow tube. Potential ligands will usually be relatively small molecules that have large diffusion coefficients. In the absence of any noncovalent interactions in solution, very steep dispersion profiles are expected for these potential ligands. However, a ligand that binds to a large target in solution, will show an apparent diffusion coefficient that is significantly reduced, thus resulting in a more extended dispersion profile.

Abstract: A method and apparatus are provided for determining rates and mechanisms of reactions in solution. The method comprises mixing reactants together and then passing the reactants, after mixing, to an electrospray or other ion source. The apparatus is configured so that the reaction time can be determined. This can either be by way of a capillary of known length and volume extending from a reaction tee or other mixing device, so that the reaction time can be determined from the capillary volume and flow rate, and/or by way of a container of fixed volume from which the reactants pass. From the ion source, ions pass into a mass spectrometer, where a mass spectrum is measured. By varying the reaction time, and measuring the different mass spectra, the rate of reaction can be determined.