Abstract: An apparatus for effecting base pair length separations of DNA fragments by matched ion paired chromatography comprising a separation column containing separation media having non-polar DNA separation surfaces, separation solution supply means, and a separation solution conduit communicating with the separation column and the separation solution supply means, and a cleaning solution valve means positioned in the separation solution conduit for injecting cleaning solution into the separation solution conduit. A process for cleaning the non-polar DNA separation surfaces in the apparatus comprising interrupting the flow of separation solvent with a block of cleaning solution injected into the flow of separation solution passing to the column, the cleaning solution containing agent which removes accumulated residues from the non-polar surface. The cleaning solution can have an alkaline pH and contain a chelating agent such as EDTA.

Abstract: A liquid chromatography apparatus with stationary and mobile phase temperature controls suitable for polynucleotide separations by MIPC and DMIPC processes. The apparatus includes heater means with a temperature control system; a matched ion polynucleotide chromatography separation column having an inlet end; a coil of capillary tubing having an inlet end and an outlet end. The outlet end of the capillary tubing is connected with the inlet end of the separation column. The inlet end of the capillary tubing comprising means for receiving process liquid, the tubing having a length of from 6 to 400 cm having a linear tubing length of heating means. The separation column and the coil of capillary tubing are enclosed in the heater means. The capillary tubing preferably is PEEK or titanium. The heater means can be an air batch oven. Preferably, it is a heat-conducting block having a first heat transfer surface, a separation column receptacle, and a capillary coil receptacle.

Abstract: Disclosed is a system and method which allows user controlled formation, and ejection of droplets of sample analyte containing solutions, thereby enabling precise user directed fractionalization and distributed collection of sample analytes.

Abstract: Non-polar polymeric separation media, such as beads or monoliths, are suitable for chromatographic separation of mixtures of polynucleotides when the surfaces of the media are unsubstituted or substituted with a hydrocarbon group having from one to 1,000,000 carbons and when the surfaces are substantially free from mutivalent cation contamination. The polymeric media provide efficient separation of polynucleotides using Matched Ion Polynucleotide Chromatography. Methods for maintaining and storing the polymeric media include treatment with multivalent cation binding agents.

Abstract: Nonporous beads having an average diameter of about 0.5-100 microns are suitable for chromatographic separation of mixtures of polynucleotides when the beads comprise a nonporous particle which are coated with a polymer or which have substantially all surface substrate groups endcapped with a non-polar hydrocarbon or substituted hydrocarbon group. The beads provide efficient separation of polynucleotides using Matched Ion Polynucleotide Chromatography.

Abstract: Improved liquid chromatography systems having components made of titanium, stainless steel, or organic polymeric material are useful in the separation of polynucleotide fragments, particularly large fragments of double-stranded polynucleotides, by Matched Ion Polynucleotide Chromatography (MIPC). The titanium, stainless steel, or polymeric components are treated so that they do not release multivalent cations into aqueous solutions flowing through the chromatography system. Alternatively, or in addition to utilizing materials made of the components listed above, a multivalent cation capture resin placed upstream of the separation column can be employed to remove multivalent ions from the system. The multivalent cation capture resin can be contained in a guard disk, a guard column, or a guard cartridge.

Abstract: A method for analyzing a sample of double stranded DNA to determine the presence of a mutation therein comprises contacting the sample with a mutation site binding reagent, and chromatographically separating and detecting the product. The chromatographic separation can be performed using Matched Ion Polynucleotide Chromatography, size exclusion chromatography, ion exchange chromatography, or reverse phase chromatography. The mutation site binding reagent can be an enzyme or a non-proteinaceous chemical reagent. In one embodiment, a mutation site binding reagent binds to the site of mutation and alters the chromatographic retention time. In another embodiment, a mutation site binding reagent cleaves at the site of mutation, resulting in an increase in the number of fragments.

Abstract: Mixtures of dsDNA fragments are separated by Matched Ion Polynucleotide Chromatography (MIPC) using an isocratic mobile phase to elute polynucleic acid from an MIPC column. The use of isocratic elution conditions provides a marked improvement in the separation of dsDNA fragments compared to gradient elution conditions. Isocratic elution can also be used to effect an improved separation of heteroduplex and homoduplex mixtures when the chromatography is performed under partially denaturing conditions. In addition, dsDNA fragments are bound to the stationary phase under isocratic conditions until a solvent concentration is reached which releases fragments of a particular base pair length range. This separation process is different from the equilibrium partitioning process observed under gradient elution conditions.

Abstract: Improved liquid chromatography systems having components made of titanium, stainless steel, or organic polymeric material are useful in the separation of polynucleotide fragments, particularly large fragments of double-stranded polynucleotides, by Matched Ion Polynucleotide Chromatography (MIPC). The titanium, stainless steel, or polymeric components are treated so that they do not release multivalent cations into aqueous solutions flowing through the chromatography system. Alternatively, or in addition to utilizing materials made of the components listed above, a multivalent cation capture resin placed upstream of the separation column can be employed to remove multivalent ions from the system. The multivalent cation capture resin can be contained in a guard disk, a guard column, or a guard cartridge.

Abstract: Systems and methods for inducing and detecting sample analyte(s) identifying fluorescence are disclosed. In particular, a system which includes at least two fiber optic means, within a "throw-away" modular component system component with at least four ports, in which sample analyte fluorescence is caused to occur, by the application of energy to sample analyte(s), is disclosed. The present invention system provides that sample analyte(s) fluorescence inducing energy be entered via an optic fiber means and that produced fluorescence be provided to a detector system via a second optic fiber means. A preferred source of sample analyte(s) fluorescence inducing energy includes lasers, and a preferred method by which to provide sample analyte(s) to the present invention system involves electrophoresis.

Abstract: Disclosed are a laser ablation system and method for determining the presence of trace elements in liquid samples such as oils, and/or in powder samples. A sample containing microporous membrane is utilized to prevent "splashing", "splattering" and/or "scattering" of liquid and/or powder sample when laser contained sample effectively "nebulizing" energy is applied. The present invention is typically used in combination with an inductively coupled plasma and a detector system, such as an Atomic Emission Spectrometer or Mass Spectrometer.

Abstract: The present invention is a system for nebulizing sample analyte containing solutions which allows liquid solution and gas entry, and is tyically utilized in combination or integration with an interface for directing sample analyte containing solution which is nebulized. The present invention provides improvement in the form of system design that prevents sample delivery tube component damage, sample solution electrical charging, sample solution "re-nebulization" effects, and sample analyte carry-over memory effects during a present invention method of use for introducing nebulized sample analyte containing solution into, for instance, a mass-spectrometer sample analysis system.

Abstract: Improved liquid chromatography systems having components made of titanium, stainless steel, or organic polymeric material are useful in the separation of polynucleotide fragments, particularly large fragments of double-stranded polynucleotides, by Matched Ion Polynucleotide Chromatography (MIPC). The titanium, stainless steel, or polymeric components are treated so that they do not release multivalent cations into aqueous solutions flowing through the chromatography system. Alternatively, or in addition to utilizing materials made of the components listed above, a multivalent cation capture resin placed upstream of the separation column can be employed to remove multivalent ions from the system. The multivalent cation capture resin can be contained in a guard disk, a guard column, or a guard cartridge.

Abstract: A batch process for obtaining polynucleotide fragments, such as dsDNA, having a selected size from a mixture of polynucleotide fragments including the steps of a) applying a solution of the mixture of polynucleotide fragments and a counterion agent to a binding medium having a hydrophobic surface; b) contacting the binding medium with a first stripping solvent and counterion agent, the first stripping solvent having a concentration of organic component sufficient to release from the binding medium all polynucleotide fragments having a size smaller than the selected size, and removing the first stripping solvent from the binding medium; and c) contacting the binding medium with a second stripping solvent having a concentration of organic component sufficient to release from the binding medium the polynucleotide fragments having the selected size, and removing the second stripping solvent from the binding medium. The binding medium can be organic polymer or inorganic particle beads.

Abstract: The invention recognizes the deleterious effects of trace, and even undetectable amounts of multivalent cations on the separation of mixtures of polynucleotides, especially double stranded polynucleotides, and provides an improved method for separating such mixtures on wide pore, non-polar separation media by eliminating multivalent cations from the all aspects of the separation process. This is accomplished by using components in the separation process which are materials which do not release metal cations. In addition, the use of cation capture resins and other methods to remove residual traces of multivalent cations from eluting solvents, sample solutions, separation media, and system components is described. It is also important to remove any traces or organic contaminants from solvents solutions and system parts.

Abstract: A long-path absorbance-cell optical imaging system, appropriate for use in cold vapor mercury analysis, which long-path absorbance-cell optical imaging system achieves decreased internal reflection mediated system-element-parameter-change-based sensitivity in use, by appropriate placement of apertures, is disclosed.

Abstract: Improved liquid chromatography systems having components made of titanium, coated stainless steel, or organic polymeric material are useful in the separation of nucleic acid fragments, particularly large fragments of double-stranded nucleic acids, by ion pairing reverse phase chromatography. The titanium, coated stainless steel, or polymeric components do not release multivalent cations into aqueous solutions flowing through the chromatography system. Alternatively, or in addition to utilizing materials made of the components listed above, a multivalent cation capture resin placed upstream of the separation column may be employed to remove multivalent ions from the system. The multivalent cation capture resin may be contained in a guard disk, a guard column, or a guard cartridge.