Abstract: The invention provides a compound of formula (I): or a pharmaceutically-acceptable salt thereof, that is an inhibitor of JAK kinases. The invention also provides pharmaceutical compositions comprising such compound, a crystalline form, methods of using such compound to treat inflammatory skin diseases and other diseases, and processes and intermediates useful for preparing such compound.

Abstract: The aryl sulfonamide compounds of this invention have powerful and cell-type specific Bcl inhibitory activity. Selected compounds in this class promote apoptosis in senescent cells, and are being developed for treating senescent-related conditions. Selected compounds in this class promote apoptosis in cancer cells, and can be developed as chemotherapeutic agents.

Abstract: The invention provides compounds which are prodrugs of a JAK inhibitor agent for the targeted delivery of the JAK inhibitor to the gastrointestinal tract of a mammal. The invention also provides pharmaceutical compositions comprising the compounds, methods of using the compounds to treat gastrointestinal inflammatory diseases, and processes and intermediates useful for preparing the compounds.

Abstract: Disclosed are methods for treating ulcerative colitis using a compound of the formula: or a pharmaceutically-acceptable salt thereof.

Abstract: This disclosure provides compounds with Bcl inhibitory activity based on a new chemical scaffold. The phospholidine compounds can include a P-phenyl phospholidine moiety which is substituted with an N-aryl or N-heteroaryl group. The P-phenyl phospholidine moiety can be optionally substituted at phosphorus with thio (?S) instead of oxo (?O). A second heteroatom attached to phosphorus can be cyclically linked to the N-substituted nitrogen atom of the phospholidine that is attached to the phosphorus to provide, together with the phosphorus atom through which they are connected, a heterocyclic ring. By incorporating such a cyclic constraint between two phosphorus substituents of the core linking moiety a favorable binding conformation can be promoted in the compounds. Selected compounds promote apoptosis in senescent cells, and can be developed for treating senescent-related conditions, such as osteoarthritis, ophthalmic disease, pulmonary disease, and atherosclerosis.

Abstract: This disclosure provides compounds with Bcl inhibitory activity based on a new chemical scaffold. Phosphonamidate compounds typically include a P-phenyl phosphonamidate moiety which is substituted with an N-aryl or N-heteroaryl group. The P-phenyl phosphonamidate moiety may be optionally substituted at phosphorus with thio (?S) instead of oxo (?O), and/or with a thioxy group or a second amino group instead of an oxy group. One of the heteroatoms attached to phosphorus may be cyclically linked to the N-substituted nitrogen atom that is attached to the phosphorus to provide a heterocyclic ring. By incorporating such a cyclic constraint between two phosphorus substituents of the core linking moiety, a favorable binding conformation may be promoted in the compounds. Selected compounds promote apoptosis in senescent cells, and can be developed for treating senescent-related conditions, such as osteoarthritis, ophthalmic disease, pulmonary disease, and atherosclerosis.

Abstract: Provided herein, inter alia, are compounds and methods for modulating Bruton's Tyrosine Kinase.

Abstract: The aryl sulfonamide compounds of this invention have powerful and cell-type specific Bcl inhibitory activity. Selected compounds in this class promote apoptosis in senescent cells, and are being developed for treating senescent-related conditions. Selected compounds in this class promote apoptosis in cancer cells, and can be developed as chemotherapeutic agents.

Abstract: The invention provides a compound of formula (I): or a pharmaceutically-acceptable salt thereof, that is an inhibitor of JAK kinases. The invention also provides pharmaceutical compositions comprising such compound, a crystalline form, methods of using such compound to treat inflammatory skin diseases and other diseases, and processes and intermediates useful for preparing such compound.

Abstract: Senescent cell medicine encompasses the paradigm that many conditions that are associated with aging or tissue damage are caused or mediated by senescent cells. This disclosure shows that HSP90, pI3-kinase, proteasome, HDAC, and p97 pathways are all active in senescent cells, and can be used as an effective means for removing senescent cells from a target tissue. Exemplary inhibitors of each of these pathways are provided. Also provided is a new genus of p97 inhibitor molecules. The structure includes a core 4 amino pyrimidine ring system, substituted at the 2 position with a nitrogen atom of an amino substituent or a N heterocycle. The 4 amino substituent of the core ring system is optionally linked to a substituted phenyl group. Any of the inhibitors referred to in this disclosure can be screened for senolytic activity and developed for the treatment of conditions such as osteoarthritis, ophthalmic disease, pulmonary disease, and atherosclerosis.

Abstract: This invention is based on the discovery that many lung diseases associated with aging are mediated at least in part by cells bearing a senescent phenotype. Senescent cells accumulate with age, and express factors that contribute to the pathophysiology of age related conditions. The severity of age-related conditions typically correlates with the abundance of senescent cells: thus, clearing senescent cells can help abrogate the condition: providing symptomatic relief, and potentially inhibiting disease progression. In accordance with this invention, a family of Bcl protein inhibitors has been developed for the treatment of lung diseases. These senolytic agents have an appropriate dose and specificity profile to be effective in the clinical management of previously intractable pulmonary diseases.

Abstract: The aryl sulfonamide compounds of this invention have powerful and cell-type specific Bcl inhibitory activity. Selected compounds in this class promote apoptosis in senescent cells, and are being developed for treating senescent-related conditions. Selected compounds in this class promote apoptosis in cancer cells, and can be developed as chemotherapeutic agents.

Abstract: The invention provides a compound of formula (I): or a pharmaceutically-acceptable salt thereof, that is an inhibitor of JAK kinases. The invention also provides pharmaceutical compositions comprising such compound, a crystalline form, methods of using such compound to treat inflammatory skin diseases and other diseases, and processes and intermediates useful for preparing such compound.

Abstract: This disclosure provides compounds with Bcl inhibitory activity based on a new chemical scaffold, as shown in Formula (I). The phospholidine compounds can include a P-phenyl phospholidine moiety which is substituted with an N-aryl or N-heteroaryl group. The P-phenyl phospholidine moiety can be optionally substituted at phosphorus with thio (?S) instead of oxo (?O). A second heteroatom attached to phosphorus can be cyclically linked to the N-substituted nitrogen atom of the phospholidine that is attached to the phosphorus to provide, together with the phosphorus atom through which they are connected, a heterocyclic ring. By incorporating such a cyclic constraint between two phosphorus substituents of the core linking moiety a favorable binding conformation can be promoted in the compounds. Selected compounds promote apoptosis in senescent cells, and can be developed for treating senescent-related conditions, such as osteoarthritis, ophthalmic disease, pulmonary disease, and atherosclerosis.

Abstract: The invention relates to glucuronide prodrug compounds of Janus kinase (JAK) inhibitors having formula I: where W1, R1 and A1 are as defined. The invention also relates to pharmaceutical compositions comprising such compounds; methods of using such compounds to treat gastrointestinal inflammatory diseases; and processes and intermediates for preparing such compounds.

Abstract: This disclosure provides compounds with Bcl inhibitory activity based on a new chemical scaffold, as shown in Formula (I): Phosphonamidate compounds disclosed herein typically include a P-phenyl phosphonamidate moiety which is substituted with an N-aryl or N-heteroaryl group. The P-phenyl phosphonamidate moiety may be optionally substituted at phosphorus with thio (?S) instead of oxo (?O), and/or with a thioxy group or a second amino group instead of an oxy group. One of the heteroatoms attached to phosphorus may be cyclically linked to the N-substituted nitrogen atom that is attached to the phosphorus to provide a heterocyclic ring. By incorporating such a cyclic constraint between two phosphorus substituents of the core linking moiety, a favorable binding conformation may be promoted in the compounds. Selected compounds promote apoptosis in senescent cells, and can be developed for treating senescent-related conditions, such as osteoarthritis, ophthalmic disease, pulmonary disease, and atherosclerosis.

Abstract: The aryl sulfonamide compounds of this invention have powerful and cell-type specific Bcl inhibitory activity. Compounds of this invention include compounds according to formula (I): Selected compounds in this class promote apoptosis in senescent cells, and are being developed for treating senescent-related conditions. Selected compounds in this class promote apoptosis in cancer cells, and can be developed as chemotherapeutic agents.

Abstract: This disclosure provides compounds with Bcl inhibitory activity based on a new chemical scaffold. Acyl phosphonamidate compounds may include a P-phenyl phosphonamidate moiety which is N-acylated with an aroyl or heteroaroyl group. The P-phenyl phosphonamidate moiety can be optionally substituted at phosphorus with thio (?S) instead of oxo (?O), and/or with a thioxy group or a second amino group instead of an oxy group. One of the heteroatoms attached to phosphorus can be cyclically linked to a carbon atom of the adjacent phenyl ring attached to the phosphorus to provide, together with the phosphorus atom through which they are connected, a heterocyclic ring. By incorporating such a cyclic constraint between two phosphorus substituents of the core linking moiety a favorable binding conformation can be promoted in the compounds.

Abstract: This invention is based on the discovery that many lung diseases associated with aging are mediated at least in part by cells bearing a senescent phenotype. Senescent cells accumulate with age, and express factors that contribute to the pathophysiology of age related conditions. The severity of age-related conditions typically correlates with the abundance of senescent cells: thus, clearing senescent cells can help abrogate the condition: providing symptomatic relief, and potentially inhibiting disease progression. In accordance with this invention, a family of Bcl protein inhibitors has been developed for the treatment of lung diseases. These senolytic agents have an appropriate dose and specificity profile to be effective in the clinical management of previously intractable pulmonary diseases.

Abstract: The proteasome inhibitors of this invention include peptide-based compounds with a short linear sequence of amino acids. An oxo or thio group is attached to the N-terminal amino acid. A protein-reactive electrophilic group such as an epoxyketone, an aziridinylketone, or a beta-lactone is attached to the C-terminal amino acid. Upon contact with a proteasome complex in a target cell, the electrophilic group reacts with a functional group in or near a binding pocket or active site of the proteasome, forming a covalent bond and thereby inactivating the proteasome. These and other proteasome inhibitors can be screened for binding affinity and an ability to selectively eliminate senescent cells or cancer cells. Compounds that selectively remove senescent cells can be developed for the treatment of conditions such as osteoarthritis, ophthalmic disease, pulmonary disease, and atherosclerosis.