Abstract: An apparatus and method for synthesizing a combinatorial library comprising a plurality of chemical compounds such that the chemical composition of each compound is easily tracked. The library compounds are synthesized on solid-phase supports, which are spatially arranged in frames during synthesis according to a predetermined protocol, such that each solid-phase support passes through a series of unique spatial 2D or 3D addresses by which the chemical composition of each compound may be determined at any point during synthesis. Solid-phase supports include hollow tubular-shaped lanterns and gears.

Abstract: A technique is disclosed for generating nonrandom combinatorial libraries on solid phase supports in which each of a set of predetermined species of test compounds is present on a predetermined number of solid phase supports, preferably on only one, and each solid phase support has only a single species of test compound. Each of the predetermined species of test compounds is prepared with absolute certainty because the technique does not employ any random division of the solid phase supports. Rather, the method is based on the stepwise division of a continuous solid phase support matrix prior to each synthetic step in which more than one type of subunit is added. Non-limiting examples of matrices of the solid phase supports include polypropylene membranes, polytetrafluoropropylene membranes and cotton thread. The combinatorial libraries made by the technique are also disclosed.

Abstract: The invention relates to libraries of synthetic test compound attached to separate phase synthesis supports. In particular, the invention relates to libraries of synthetic test compound attached to separate phase synthesis supports that also contain coding molecules that encode the structure of the synthetic test compound. The molecules may be polymers or multiple nonpolymeric molecules. Each of the solid phase synthesis support beads contains a single type of synthetic test compound. The synthetic test compound can have backbone structures with linkages such as amide, urea, carbamate (i.e., urethane), ester, amino, sulfide, disulfide, or carbon--carbon, such as alkane and alkene, or any combination thereof. Examples of subunits suited for the different linkage chemistries are provided.

Abstract: The invention provides compounds which specifically inhibit factor Xa activity. The compounds consist of the structure X.sub.1 -YIR-X.sub.2, wherein X.sub.1 is H, acyl, alkyl, acylalkyl, arylalkyl or one or more amino acids, and X.sub.2 is a modified C-terminal group, one or more carboxy-protecting groups or one or more amino acids or other substituent, and Y, I and R are tyrosine, isoleucine and arginine, respectively, or peptidomimetic or organic structures that possess the same functional activity as Y, I and R, respectively. In addition, the present invention provides a compound having the structure A1-A2-(A3).sub.m --B, where m is 0 or 1. A compound of the invention can be linear or cyclic and can be about 2 and 43 residues in length. A compound of the invention is characterized, in part, in that it exhibits a specific inhibition of factor Xa activity with a K.sub.i of .ltoreq.100 .mu.M, preferably .ltoreq.

Abstract: The invention concerns libraries of chemical compounds, that are useful in medicinal chemistry and related arts, their methods of manufacture and methods of their use. In one embodiment the individual chemical species of the library are synthesized aleatoricly, i.e, by a process involving chance. The chemical species of the library are used while attached to solid phase supports. The library differs from previously disclosed libraries that were intended to be screened while in solid phase in that each individual solid phase support or identifiable portion of a solid phase array displays many species of ligands, collectively termed a "set." The library is constructed so that each set contains a single invariant structure, common to all the species of ligands attached to the particular solid phase support, which is termed a "motif." The invention teaches that libraries of motifs can be employed advantageously compared to known libraries wherein a single species is present on each support.

Abstract: The invention relates to libraries of synthetic test compound attached to separate phase synthesis supports that also contain coding molecules that encode the structure of the synthetic test compound. The molecules may be polymers or multiple nonpolymeric molecules. The synthetic test compound can have backbone structures with linkages such as amide, urea, carbamate (i.e., urethane), ester, amino, sulfide, disulfide, or carbon-carbon, such as alkane and alkene, or any combination thereof. Examples of subunits suited for the different linkage chemistries are provided. The synthetic test compound can also be molecular scaffolds, such as derivatives of monocyclic of bicyclic carbohydrates, steroids, sugars, heterocyclic structures, polyaromatic structures, or other structures capable of acting as a scaffolding. Examples of suitable molecular scaffolds are provided.

Abstract: A technique for generating nonrandom combinatorial libraries on solid phase supports in which each of a set of predetermined species of test compounds is present on a predetermined number of solid phase supports, preferably on only one, and each solid phase support has only a single species of test compound. Each of the predetermined species of test compounds is prepared with absolute certainty because the technique does not employ any random division of the solid phase supports. Rather, the method is based on the stepwise division of a continuous solid phase support matrix prior to each synthetic step in which more than one type of subunit is added. Non-limiting examples of matrices of the solid phase supports include polypropylene membranes, polytetrafluoropropylene membranes and cotton thread. The combinatorial libraries made by the technique are also disclosed.

Abstract: The present invention is directed to linkers based on ester bond linkages, especially iminodiacetic acid ester bond linkages, for use in solid phase peptide synthesis. In particular, the invention is directed to cleavable linkers that can release peptide from the solid phase support under relatively mild conditions by formation of a diketopiperazine or other cyclic structure, such that the cyclic structure remains on the solid phase support, and, in a second cleavage, under more stringent conditions of high pH. The invention is further directed to solid phase supports prepared with multiple cleavable linkers, including a linker that is cleaved by formation of a cyclic product. One such second linker is an ester of hydroxymethylbenzoic acid, or esters formed by carboxy groups of aspartic or glutamic acid.

Abstract: A solid phase synthesis system is provided by employing a fully automated robot that operates with a novel timing protocol for handling multiple synthetic tasks efficiently. The novel timing protocol is realized by performing steps in the synthesis cycles for different compounds, such as peptides, concurrently rather than on a sequential basis.

Abstract: The present invention relates to methods for determining the amino acid composition, and more preferably the sequence, of a peptide using mass spectrometric techniques. The method is particularly useful for sequencing peptides isolated from natural sources or from libraries of peptides that have been prepared synthetically, and for peptides that are not amenable to Edman degradation sequencing. In one embodiment, the method for determining the amino acid composition or sequence of a peptide comprises determining the difference of the mass of the peptide from the mass of a deuterium-hydrogen exchanged peptide, and from this difference determining the number of exchangeable (labile) hydrogen atoms (protons). Candidate peptides having amino acid compositions or sequences that do not contain the observed number of exchangeable protons are eliminated.