The present invention relates to a process for treating a polyamide-based composition which is intended to be recycled. More particularly, the present invention relates to a process for treating a composition, typically a powder based on untransformed polyamides during the manufacture of an object in 3D printing. The invention also relates to the use of the recycled composition.

Disclosed are methods of preparing a cross-linked polymeric polycarboxylic acid by cross-linking the polymeric polycarboxylic acid with cross-linking agent comprising a polyepoxide and a polyhydrazide. Also disclosed are the cross-linked polymeric polycarboxylic acids made by the process and water-absorbent polymer materials comprising the cross-linked polymeric polycarboxylic acids.

Disclosed are methods of preparing a cross-linked polymeric polycarboxylic acid by cross-linking the polymeric polycarboxylic acid with cross-linking agent comprising a polyepoxide and a polyhydrazide. Also disclosed are the cross-linked polymeric polycarboxylic acids made by the process and water-absorbent polymer materials comprising the cross-linked polymeric polycarboxylic acids.

Provided is a polymer comprising a hydrolysable polymer backbone, the polymer backbone comprising (i) monomer units with a side chain comprising a hydrophobic group; (ii) monomer units with a side chain comprising an oligoamine or polyamine; and optionally (iii) monomer units with a side chain comprising an ionizable group, as well as a method of preparing said polymer, and a method of delivering a nucleic acid and/or polypeptide to a cell using the polymer.

Provided is a polymer comprising a hydrolysable polymer backbone, the polymer backbone comprising (i) monomer units with a side chain comprising a hydrophobic group; (ii) monomer units with a side chain comprising an oligoamine or polyamine; and (iii) monomer units with a side chain comprising a polyalkylene oxide, polyglycolic acid, polylactic acid, or combination thereof, as well as a composition comprising the polymer, and a method of delivering one or more biomolecules or synthetic variants thereof to a cell using the polymer and/or the composition.

Described herein is a melt flowable polyamide composition for shaped articles, which may include thin wall connectors such as electrical connectors.

Described herein is a melt flowable polyamide composition for shaped articles, which may include thin wall connectors such as electrical connectors.

Disclosed are methods, compositions, reagents, systems, and kits to prepare and utilize branched multi-functional macromonomers, which contain a ring-opening metathesis polymerizable norbornene group, one or more reactive sites capable of undergoing click chemistry, and a terminal acyl group capable of undergoing a coupling reaction; branched multi-cargo macromonomers; and the corresponding polymers are disclosed herein. Various embodiments show that the macromonomers and polymers disclosed herein display unprecedented control of cargo loading of agents. These materials have the potential to be utilized for the treatment of diseases and conditions such as cancer and hypertension.

Disclosed are methods, compositions, reagents, systems, and kits to prepare and utilize branched multi-functional macromonomers, which contain a ring-opening metathesis polymerizable norbornene group, one or more reactive sites capable of undergoing click chemistry, and a terminal acyl group capable of undergoing a coupling reaction; branched multi-cargo macromonomers; and the corresponding polymers are disclosed herein. Various embodiments show that the macromonomers and polymers disclosed herein display unprecedented control of cargo loading of agents. These materials have the potential to be utilized for the treatment of diseases and conditions such as cancer and hypertension.

The present disclosure provides a means for preventing or suppressing the leaching of a redox mediator constituting a reagent layer in a probe of an embedded biosensor, in particular, a means capable of improving preservation stability (durability) while maintaining glucose measurement sensitivity. The high molecular weight redox polymer according to the present disclosure is represented by general formula (A1), wherein X.sup.− represents an anionic species; L represents a linker; Poly represents a high molecular weight polymer; and R.sup.1 to R.sup.8 each independently represent a hydrogen atom or a substituent. The biosensor according to the present disclosure has a working electrode, a counter electrode, a reagent layer disposed on the working electrode, and a protective film covering at least the reagent layer, and the reagent layer contains an oxidoreductase that oxidizes or dehydrogenates the analyte and at least one high molecular weight redox polymer represented by general formula (A1).

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