Abstract: Methods for performing rapid and accurate thermocycling on a sample are disclosed. Use of non-contact heating and cooling sources allows precise temperature control with sharp transitions from one temperature to another to be achieved. A wide range of temperatures can be accomplished according to these methods. In addition, thermocycling can be performed without substantial temperature gradients occurring in the sample. Apparatus for achieving these methods are also disclosed. A method for pumping a sample through microchannels on a microchip using a non-contact heat source is also disclosed.

Abstract: Methods for performing rapid and accurate thermocycling on a sample are disclosed. Use of non-contact heating and cooling sources allows precise temperature control with sharp transitions from one temperature to another to be achieved. A wide range of temperatures can be accomplished according to these methods. In addition, thermocycling can be performed without substantial temperature gradients occurring in the sample. Apparatus for achieving these methods are also disclosed. A method for pumping a sample through microchannels on a microchip using a non-contact heat source is also disclosed.

Abstract: Methods for performing rapid and accurate thermocycling on a sample are disclosed. Use of non-contact heating and cooling sources allows precise temperature control with sharp transitions from one temperature to another to be achieved. A wide range of temperatures can be accomplished according to these methods. In addition, thermocycling can be performed without substantial temperature gradients occurring in the sample. Apparatus for achieving these methods are also disclosed. A method for pumping a sample through microchannels on a microchip using a non-contact heat source is also disclosed.

Abstract: A capillary electrophoresis method for resolving transferrin glycoforms in a sample is described. The capillary comprises a lumen, an inlet and an outlet. The lumenal surface of the capillary is charge-neutral and the capillary contains a buffer containing a polymeric matrix. The transferrin sample is contacted with the inlet of the capillary. A voltage is applied to the capillary such that the inlet is a cathode and the outlet is an anode and such that the voltage is effective for resolving transferrin glycoforms. A method for diagnosing chronic alcoholism or carbohydrate-deficient glycoprotein syndrome using CE to resolve abnormal populations of transferrin glycoforms is also described.

Abstract: A preseparation processor for use in capillary electrophoresis is described. The preseparation processor contains sample processing material, preferably in the form of a membrane, for use in concentrating or chemically processing a sample, or catalyzing a chemical reaction. It is particularly suited to the concentration of dilute samples or the purification of contaminated samples. The preseparation processor facilitates reliable and reproducible separation of analytes by eliminating inconsistencies caused by a reversal of the electroosmotic flow otherwise induced by the sample processing material.