The present invention relates to a functional 3D neuronal model based on ultrashort self-assembling peptide scaffolds in accordance with the present invention, and to a method of preparing such a model. The models are suitable for in vitro drug testing, cellular replacement therapies as well as other applications.

The present invention relates to a functional 3D neuronal model based on ultrashort self-assembling peptide scaffolds in accordance with the present invention, and to a method of preparing such a model. The models are suitable for in vitro drug testing, cellular replacement therapies as well as other applications.

The present application is directed to a nanocomposite organo gel having a continuous polymeric network structure, wherein polymer chains are held together by ionic interaction between polymer chain ends, interparticle chain entanglements, layered silicate surface modifier, ionic salt, and layered silicate. The present application is also directed to methods of making and using the nanocomposite organo gel.

Crosslinked nucleotide polymers. A crosslinked nucleotide polymer may be formed by reaction of a biomass comprising DNA and/or RNA with one or more crosslinker(s). A crosslinked nucleotide polymers may be formed by a crosslinking reaction including an aza-Michael addition reaction. Crosslinked nucleotide polymers may be present in various forms and compositions and form various articles of manufacture. Crosslinked nucleotide polymers may be used in therapeutic methods, coating methods, and cell-free protein production methods.

Crosslinked nucleotide polymers. A crosslinked nucleotide polymer may be formed by reaction of a biomass comprising DNA and/or RNA with one or more crosslinker(s). A crosslinked nucleotide polymers may be formed by a crosslinking reaction including an aza-Michael addition reaction. Crosslinked nucleotide polymers may be present in various forms and compositions and form various articles of manufacture. Crosslinked nucleotide polymers may be used in therapeutic methods, coating methods, and cell-free protein production methods.

Herein provided are methods for evaluating cellulose nanofiber dispersions, comprising the steps of: (1) preparing a cellulose nanofiber dispersion; (2) adding a color material into the cellulose nanofiber dispersion; and (3) observing the cellulose nanofiber dispersion to which a colored pigment has been added with a light microscope. The methods allow for easy evaluation of whether or not agglomerates of cellulose nanofibers exist in cellulose nanofiber dispersions, which cannot be visually determined.

Herein provided are methods for evaluating cellulose nanofiber dispersions, comprising the steps of: (1) preparing a cellulose nanofiber dispersion; (2) adding a color material into the cellulose nanofiber dispersion; and (3) observing the cellulose nanofiber dispersion to which a colored pigment has been added with a light microscope. The methods allow for easy evaluation of whether or not agglomerates of cellulose nanofibers exist in cellulose nanofiber dispersions, which cannot be visually determined.

Surfactants capable of releasing and/or dissolving polymers to form water-soluble or water-dispersible polymer solutions are disclosed. In addition, polymer compositions containing a water-in-oil emulsion comprising the surfactant are provided and can be used, for example, in methods of dissolving a polymer. These surfactants and polymer compositions can be used in various industries including for water clarification, papermaking, sewage and industrial water treatment, drilling mud stabilizers, and enhanced oil recovery.

Producing a resin particle dispersion using an apparatus including: two or more resin particle dispersion production lines each including an emulsification tank in which a resin is subjected to phase inversion emulsification using two or more organic solvents and an aqueous medium to obtain a phase-inverted emulsion, a distillation tank in which the organic solvents are removed from the phase-inverted emulsion by reduced pressure distillation to obtain a resin particle dispersion, and plural distillate collection tanks that collect distillates formed during the reduced pressure distillation according to respective target distillate compositions; and a reusable storage tank that collects and stores a distillate collected in at least one collection tank among the distillates collected in the plural collection tanks in each of the two or more production lines, and delivering the distillate to the emulsification tank in at least one production line to reuse the distillate for producing a phase-inverted emulsion.

Provided are a polyamide having a structural unit represented by General Formula [1], and the like. In General Formula [1], R.sup.1 is a divalent organic group represented by General Formula [2], and R.sup.2 is a divalent organic group. In General Formula [2], n.sub.1 and n.sub.2 are each independently an integer of 0 to 4, and in a case where a plurality of R.sup.3's are present, the plurality of R.sup.3's each independently represent a monovalent substituent.