A composition comprising mesoporous aggregates of magnetic nanoparticles and free-radical producing enzyme (i.e., enzyme-bound mesoporous aggregates), wherein the mesoporous aggregates of magnetic nanoparticles have mesopores in which the free-radical-producing enzyme is embedded. Methods for synthesizing the enzyme-bound mesoporous aggregates are also described. Processes that use said enzyme-bound mesoporous aggregates for depolymerizing lignin, removing aromatic contaminants from water, and polymerizing monomers polymerizable by a free-radical reaction are also described.

The invention relates to a blood treatment device configured to dephosphorylate extracellular adenosine triphosphate (ATP), adenosine diphosphate (ADP), adenosine monophosphate (AMP) and/or lipopolysaccharide (LPS) in the blood of a patient in need thereof in an extracorporeal blood circuit, wherein the device comprises a matrix having alkaline phosphatase (AP) immobilized thereon. The invention further relates to an extracorporeal blood circuit comprising a blood treatment device of the invention and to the blood treatment device for use as a medicament or to methods of treating an infection, preferably a blood or systemic infection, such as sepsis, and/or for the treatment of sepsis-associated acute kidney injury (AKI).

Disclosed are complex coacervate core micelles comprising an enzyme capable of hydrolyzing organophosphorus compounds, such as nerve agents, and, for example, their use in remediation or decontamination of stockpiles of chemical weapons.

The present invention generally relates to photocatalytic systems comprising graphene and associated methods. Some embodiments are directed to systems comprising one or more layers of graphene having a first surface and a second, opposed surface. A light-absorbing complex may be associated with the first surface of the one or more graphene layers, and an electron donor complex may be associated with the light-absorbing complex. A catalytic complex may be associated with the first surface or the second surface of the one or more graphene layers. For example, the catalytic complex may catalyze the formation of hydrogen gas, NADH, and/or NADPH.

Described herein is a one-pot, four-enzyme cascade of enzymes, three bound to quantum dots with one enzyme free in solution, for the conversion in vitro of fumarate to 1,3-diaminopropane. The cascade operates via two distinctly different enzymatic channeling mechanisms which simultaneously function to increase the overall rate. The first three enzymes of the pathway (AspB->LysC->Asd) were able to engage in channeling in a nanoparticle displayed format, but addition of the last two enzymes to this pathway in this format (AspB->LysC->Asd->Dat->Ddc) did not result in complete channeling through the entire pathway to the final diaminopropane product. Surprisingly, replacement of the last two enzymes (Dat->Ddc) with a naturally occurring fused Dat-Ddc hybrid (Daba) provided for full channeling in this system (AspB->LysC->Asd->Daba).

A method of preparing glucaric acid comprising contacting D-glucose and oxygen with a first catalyst composition comprising a first copper radical oxidase, a single electron oxidizer, and a small molecule activator under conditions suitable for formation of glucodialdose; and contacting glucodialdose and oxygen with a second catalyst composition comprising a second copper radical oxidase, a single electron oxidizer and a small molecule activator under conditions suitable for the formation of a product mixture comprising glucaric acid or salts thereof. A method comprising contacting a sugar with a catalyst composition comprising an oxidoreductase, a single electron oxidizer and a small molecule activator under conditions suitable for the formation of one or more oxidized sugar oxidation products comprising glucaric acid wherein the oxidoreductase comprises at least two copper radical oxidases, at least two mutated copper radical oxidases or combinations thereof.

The present invention provides magnetic macroporous polymeric hybrid scaffolds for supporting and enhancing the effectiveness of bionanocatalysts (BNC). The novel scaffolds comprise cross-linked water-insoluble polymers and an approximately uniform distribution of embedded magnetic microparticles (MMP). The cross-linked polymer comprises polyvinyl alcohol (PVA) and optionally additional polymeric materials. The scaffolds may take any shape by using a cast during preparation of the scaffolds. Alternatively, the scaffolds may be ground to microparticles for use in biocatalytic reactions. Alternatively, the scaffolds may be shaped as beads for use in biocatalyst reactions. Methods for preparing and using the scaffolds are also provided.

Provided are methods of producing compounds, which are useful in synthesizing prostacyclin derivatives, such as treprostinil.

An oxygen generating system includes a vessel, an oxygen releasing ingredient, an oxygen activation ingredient, and an optional catalyst. The vessel has an outlet. When at least the oxygen releasing ingredient is mixed with the oxygen activation ingredient, oxygen is generated and is released through the outlet of the vessel.

The invention relates to a method and an apparatus for forming a lignin fraction from crude lignin which has been processed by means of a treatment step selected from enzymatic treatment, treatment with ionic liquid and their combinations. The method comprises treating the crude lignin (1) by a lignin liberation in at least one lignin liberation step (3), and separating a lignin fraction (6) in at least one separation step (5). Further, the invention relates to a lignin composition and its use.