The present invention relates to a novel compound, which enables additional hydrogen bonding with amino acids at specific positions of histone acetyltransferase (HAT) p300, through structure analysis of HAT p300. The novel compound of the present invention has a remarkably excellent effect of inhibiting HAT p300 activity and thus can be very effectively used in the prevention, alleviation, or treatment of fibrosis, which is a disease associated with activation of HAT p300.

Provided herein are an indene compound, e.g., a compound of Formula (I), and a pharmaceutical composition thereof. Also provided herein is a method of their use for treating, preventing, or ameliorating one or more symptoms of a fibrotic disease.

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The present invention relates to an amide derivative and use thereof in medicine, and specifically to an amide derivative shown as general formula (I) or a stereoisomer, solvate, metabolite, deuteride, prodrug, pharmaceutically acceptable salt or cocrystal thereof, a pharmaceutical composition containing the same, and use of the compound or the composition disclosed herein in preparing an NLRP3 inhibitor.

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Provided herein are compounds useful in the treatment of bacterial infections, pharmaceuticals comprising the same, and methods of use and preparation thereof.

Provided herein are compounds useful in the treatment of bacterial infections, pharmaceuticals comprising the same, and methods of use and preparation thereof.

The present invention describes compounds and uses thereof in applications relating to absorption of electromagnetic energy. Preferred compounds are double bond-containing compounds capable of absorbing electromagnetic radiation energy and having improved properties.

The present invention describes compounds and uses thereof in applications relating to absorption of electromagnetic energy. Preferred compounds are double bond-containing compounds capable of absorbing electromagnetic radiation energy and having improved properties.

Covalent organic frameworks (COFs) usually crystallize as insoluble powders and their processing for suitable devices has been thought to be limited. Here, it is demonstrated that COFs can be mechanically pressed into shaped objects having anisotropic ordering with preferred orientation between the hk0 and 00/ crystallographic planes. Pellets prepared from bulk COF powders impregnated with LiClO.sub.4 displayed room temperature conductivity up to 0.26 mS cm.sup.−1 and stability up to 10.0 V (vs. Li.sup.+/Li.sup.0). This outcome portends use of COFs as solid-state electrolytes in batteries.

Covalent organic frameworks (COFs) usually crystallize as insoluble powders and their processing for suitable devices has been thought to be limited. Here, it is demonstrated that COFs can be mechanically pressed into shaped objects having anisotropic ordering with preferred orientation between the hk0 and 00/ crystallographic planes. Pellets prepared from bulk COF powders impregnated with LiClO.sub.4 displayed room temperature conductivity up to 0.26 mS cm.sup.−1 and stability up to 10.0 V (vs. Li.sup.+/Li.sup.0). This outcome portends use of COFs as solid-state electrolytes in batteries.

The present disclosure relates to the field of organic light-emitting materials, and more particularly, to a thermally activated delayed fluorescence material having red, green, or blue color, a synthesis method thereof, and application thereof. The thermally activated delayed fluorescence material having red, green, or blue color has the following structural formula: ##STR00001## the present disclosure provides a novel thermally activated delayed fluorescence material having red, green, or blue color which has a lower singlet triplet energy level difference, a high RISC rate constant (kRISC), and a high photoluminescence quantum yield (PLQY). It has significant characteristics of a thermally activated delayed fluorescence material and a long service life that can be used in an electroluminescent display and a light-emitting equipment structure which are mass produced.