The present invention relates to a process of preparing a poly(anthranilamide) comprising the steps: (A) providing an anthranilate, and (B) reacting the anthranilate by polycondensation and separation of the alcohol on which the anthranilate is based in the presence of a catalyst to poly(anthranilamide), the poly(anthranilamides) obtained in this way and their use in the production of fibers of composite materials.

The present invention relates to a process of preparing a poly(anthranilamide) comprising the steps: (A) providing an anthranilate, and (B) reacting the anthranilate by polycondensation and separation of the alcohol on which the anthranilate is based in the presence of a catalyst to poly(anthranilamide), the poly(anthranilamides) obtained in this way and their use in the production of fibers of composite materials.

The present disclosure relates to the field of polymer chemistry and more particularly to poly(sarcosine) polymers and uses thereof. The disclosure is also directed to compositions comprising a protein and a poly(sarcosine) polymer and uses thereof.

A process tear production of high molecular weight polyamide polymers, such as 6/66 copolymers, using a reactant stream that includes at least one lactam and cyclic oligomers. The stream is reacted with at least one diamine at an elevated temperature ring-open the cyclic oligomers to produce amide pre-polymers that are end-capped with amine groups. The pre-polymers are then reacted with at least one diacid at an elevated temperature to form polyamide 6/66 copolymers. The cyclic oligomers may be formed as by-products during standard polymerization of polyamide polymers from monomers such as caprolactam, hexamethylene diamine and adipic acid.

The present disclosure is directed to novel lipidated poly(amino acid)s (LPAAs). The present disclosure is further related to processes for preparing such novel lipidated poly(amino acid)s (LPAAs) and for preparing novel lipidated poly(amino acid)s nanoparticles (LPAANPs). Additionally, the present disclosure relates to processes for utilizing lipidated poly(amino acid)s (LPAAs) that are biocompatible and capable of drug delivery.

The present disclosure is directed to novel lipidated poly(amino acid)s (LPAAs). The present disclosure is further related to processes for preparing such novel lipidated poly(amino acid)s (LPAAs) and for preparing novel lipidated poly(amino acid)s nanoparticles (LPAANPs). Additionally, the present disclosure relates to processes for utilizing lipidated poly(amino acid)s (LPAAs) that are biocompatible and capable of drug delivery.

The present invention relates to a polyamide powder having a high glass transition temperature and to the corresponding preparation method. The invention also relates to the articles made therefrom and to a method for the production thereof.

The present invention relates to a polyamide powder having a high glass transition temperature and to the corresponding preparation method. The invention also relates to the articles made therefrom and to a method for the production thereof.

A regulation method for preparing γ-polyglutamic acid by sludge substrate fermentation includes: 1) extraction of glutamic acid from sludge protein (high pressure hydrothermal treatment, gravity pressure filtration treatment), 2) secondary metabolic synthesis of γ-polyglutamic acid (activation of domesticated strains and secondary metabolic fermentation strains); and 3) preparation of pure γ-polyglutamic acid (acidification, centrifugation, filtration, precipitation based on polar repulsion, purification, impurity removal and drying). The present invention realizes a recycling of high-value carbon and nitrogen sources of sludge without secondary pollution, and has advantages of simplified operation, good feasibility, and low preparation cost. The synthesized γ-polyglutamic acid has high economic value and broad application prospect.

A method for producing a polycondensate powder dispersion, characterised in that it includes at least one step of polycondensation: i) of at least one diester and at least one diamine, and/or ii) at least one amino ester, while stirring, in a solvent that can solubilise both the diamine and the diester and/or the amino ester but not the polyamide that forms during the polycondensation, at a temperature between 30° C. and the boiling temperature of the solvent, in order to produce a powder precipitate dispersed in the solvent.