Abstract: A method for coimmobilizing two or more biomolecules on a substrate in a defined ratio is disclosed. The method uses a copolymer conjugated to a number, N, of different types of oligonucleotides. The copolymer can be adsorbed to the surface of the substrate. N types of oligonucleotides complementary to the copolymer-bound oligonucleotides can be conjugated to N types of biomolecules. The types of the copolymer-bound oligonucleotides can be mixed in a defined ratio then adsorbed to the surface. The biomolecule-bound complementary oligonucletides can be conjugated to the copolymer-oligonucleotides to create a substrate with the biomolecules coimmobilized in a defined ratio. The invention also relates to a substrate prepared by the method of the invention.

Abstract: A continuous temperature-gradient incubation apparatus designed to solve the problem of moving of liquid vapor generated on the high-temperature side toward the low-temperature side to thereby cause condensation.

Abstract: A high throughput preparation of a plurality of different lubricating oil compositions for combinatorial libraries and subsequent high throughput screening for lubricant performance is provided. The methods can advantageously be optimized using combinatorial chemistry, in which a database of combinations of lubricating oil compositions are generated. As market conditions vary and/or product requirements or customer specifications change, conditions suitable for forming desired products can be identified with little or no downtime.

Abstract: The present invention relates to systems and methods for generating polymorphs of compounds. In particular, the present invention provides high throughput systems and methods for generating and identifying new crystalline polymorphs that find use as improved drugs, pigments, explosives, nonlinear optical crystals, solid-state reactive compounds, and other polymorphic materials.

Abstract: A method of producing a chemical compound library comprises extracting at least one extract from at least one species of plant; processing at least one of the extract(s) to remove at least one type of chemical interference to produce a processed extract; chromatographically separating the processed extract into a plurality of chromatographic fractions, each containing an amount of chemical compounds; determining the amount of chemical compounds in at least one of the chromatographic fractions; and normalizing the chromatographic fractions in which the amounts were determined to produce normalized chromatographic fractions, each such fraction comprising from about 1 microgram to about 500 micrograms of each of from one to seven chemical compounds that were present in lower concentrations in the extract and that each have a log P of from about ?1 to about 5 and a molecular weight less than about 1000 Daltons; thereby to produce a chemical compound library from at least one species of plant.

Abstract: A method of improving signal-to-noise performance of a probe. A probe or set of probes is provided for hybridization with a sample. The probe or set of probes is hybridized with the sample at a first hybridization stringency over a first hybridization time period. Following the hybridization over the first hybridization time period, the probe or set of probes is hybridized with the sample at a second hybridization stringency over a second hybridization time period. A method of improving signal-to-noise performance of probes on an array includes providing a sample containing sequences that provide perfect complementary matches to sequences contained on at least some of said probes; and hybridizing the probes with the sample, while cycling the stringency of hybridization conditions during the hybridization.

Abstract: A high throughput preparation of a plurality of different lubricating oil compositions for combinatorial libraries and subsequent high throughput screening for lubricant performance is provided. The methods can advantageously be optimized using combinatorial chemistry, in which a database of combinations of lubricating oil compositions are generated. As market conditions vary and/or product requirements or customer specifications change, conditions suitable for forming desired products can be identified with little or no downtime.