A ligand having the structure or its enantiomer; (I) wherein: each one of R.sub.a, R.sub.b, R.sub.c and R.sub.d is selected from alkyl, cycloalkyl, and aryl; the bridge group is selected from CH.sub.2NH; *CH(CH.sub.3)NH(C*,R); and the organocatalyst is an organic molecule catalyst covalently bound to the bridge group. Also, a catalyst having the structure or its enantiomer: (II) wherein: each one of R.sub.a, R.sub.b, R.sub.c and R.sub.d is selected from alkyl, cycloalkyl, and aryl; the bridge group is selected from CH.sub.2NH; *CH(CH.sub.3)NH(C*,R); and *CH(CH.sub.3)NH(C*,S); the organocatalyst is an organic molecule catalyst covalently bound to the bridge group; and M is selected from the group consisting of Rh, Pd, Cu, Ru, Ir, Ag, Au, Zn, Ni, Co, and Fe. ##STR00001##

Disclosed are compounds, methods, reagents, systems, and kits for the preparation and utilization of monomeric or polymeric metal-based compounds. These metal-based compounds are organometallic catalysts composed of substituted dipyrrin ligands bound to transition metals. C—H bond functionalization catalysis can be performed with the disclosed organometallic catalysts to yield C—N bonds to generate substituted bicyclic, spiro, and fused nitrogen-containing heterocycles, all common motifs in various pharmaceutical and bioactive molecules.

Provided herein are a method of Ru(II)-catalyzed enantioselective synthesis of a cyclic compound and cyclic compounds formed therefrom. The method includes providing a precursor compound having an unfunctionalized C—H bond and activating the unfunctionalized C—H bond by reacting the precursor compound in the presence of co-catalysts including a Ru(II) arene complex and a chiral transient directing group (CTDG).

[Problem] To provide a novel artificial protein catalyst that enables the protection of a catalyst from substances in vivo and has potential usefulness in therapeutic in vivo synthetic chemistry.

[Solution] Provided is a complex of a protein and a catalyst selected from a metal catalyst or organic catalyst. In the complex according to the present invention, the protein is a protein having a hydrophobic pocket in the three-dimensional structure thereof, and the catalyst is housed in the hydrophobic pocket so that the catalyst is not or substantially not exposed to a hydrophilic environment.

Various embodiments disclosed relate to a method of oxidizing sulfur-containing compounds. The method involves contacting a sulfur-containing compound with a helmet phthalocyaninato-type catalyst in the presence of an oxidant. The present invention also provides a method of removing undesired sulfur-containing compounds from a fluid, such as natural gas, crude oil or an aqueous waste stream.

Provided in some aspects are methods for light-controlled in situ surface patterning of a substrate comprising a step of blocking or ablating oligonucleotide molecules in a boundary region separating a plurality of spot regions, and attaching oligonucleotides to oligonucleotide molecules in a first one or more of the spot regions.

A method for manufacturing a modified porous organic framework includes steps as follows. A mixed solution is provided. The mixed solution includes a porous organic framework, a plurality of group donors and a solvent. The porous organic framework includes a plurality of first ligands. Each of the first ligands includes at least one tetrazine group. Each of the group donors includes a reactive group and a modifying group covalently connected with each other. The reactive groups are alkenyl groups, alkynyl groups, aldehyde groups, ketone groups or a combination thereof. A modifying step is conducted, wherein at least one of the reactive groups of the group donors is reacted with at least one of the tetrazine groups of the first ligands, so that at least one of the modifying groups of the group donors is covalently connected with the porous organic framework, whereby the modified porous organic framework is obtained.

Various embodiments disclosed relate to a method of oxidizing sulfur-containing compounds. The method involves contacting a sulfur-containing compound with a helmet phthalocyaninato-type catalyst in the presence of an oxidant. The present invention also provides a method of removing undesired sulfur-containing compounds from a fluid, such as natural gas, crude oil or an aqueous waste stream.

Embodiments of the present disclosure relate to methods, compositions, and systems for proximity-based, photoactivated labeling of molecules. Molecules may be labeled via activation of a ligated photocatalyst capable of transmitting energy to a proximal biomolecular labeling agent. Depending on the activated half-life and diffusion coefficient of the labeling agent, molecules within a particular vicinity of the ligated photocatalyst may be labeled but molecules outside the vicinity will not be labeled.