Ink formulations comprising bioactive particles, methods of printing the inks into three-dimensional (3D) structures, and methods of making the inks are provided. Also provided are objects, such as tissue growth scaffolds and artificial bone, made from the inks, methods of forming the objects using 3D printing techniques, and method for growing tissue on the tissue growth scaffolds. The inks comprise a plurality of bioactive ceramic particles, a biocompatible polymer binder, optionally at least one bioactive factor, and a solvent.

Ink formulations comprising bioactive particles, methods of printing the inks into three-dimensional (3D) structures, and methods of making the inks are provided. Also provided are objects, such as tissue growth scaffolds and artificial bone, made from the inks, methods of forming the objects using 3D printing techniques, and method for growing tissue on the tissue growth scaffolds. The inks comprise a plurality of bioactive ceramic particles, a biocompatible polymer binder, optionally at least one bioactive factor, and a solvent.

Ink formulations comprising bioactive particles, methods of printing the inks into three-dimensional (3D) structures, and methods of making the inks are provided. Also provided are objects, such as tissue growth scaffolds and artificial bone, made from the inks, methods of forming the objects using 3D printing techniques, and method for growing tissue on the tissue growth scaffolds. The inks comprise a plurality of bioactive ceramic particles, a biocompatible polymer binder, optionally at least one bioactive factor, and a solvent.

The invention relates to a polymer comprising: a) at least one polyether polyester copolymer segment, wherein the polyether polyester copolymer comprises ether units selected from the group consisting of the formula (II) —[CR.sup.1.sub.2].sub.n—O—, wherein n is an integer of 2 to 4, R.sup.1 represent independent of each other organic groups having 1 to 30 carbon atoms or hydrogen, and wherein in case n is equal to 2 at least one of the R.sup.1 represents an ether group having the formula —R.sup.2—O—R.sup.3, wherein R.sup.2 and R.sup.3 independent of each other represent organic groups having 1 to 30 carbon atoms, and b) at least one polysiloxane segment linked to the at least one polyether polyester copolymer segment.

The invention relates to a polymer comprising: a) at least one polyether polyester copolymer segment, wherein the polyether polyester copolymer comprises ether units selected from the group consisting of the formula (II) —[CR.sup.1.sub.2].sub.n—O—, wherein n is an integer of 2 to 4, R.sup.1 represent independent of each other organic groups having 1 to 30 carbon atoms or hydrogen, and wherein in case n is equal to 2 at least one of the R.sup.1 represents an ether group having the formula —R.sup.2—O—R.sup.3, wherein R.sup.2 and R.sup.3 independent of each other represent organic groups having 1 to 30 carbon atoms, and b) at least one polysiloxane segment linked to the at least one polyether polyester copolymer segment.

Process for increasingly producing D-Lactide and meso lactide by depolymerizing by back biting polylactide (PLA) said process which comprises: (i) Depolymerizing polylactide into its corresponding dimeric cyclic esters by heating the polylactide in the presence of a catalyst system comprising a catalyst and a co-catalyst in a reaction zone at temperature and pressure at which the polylactide is molten; (ii) Forming a vapor product stream from the reaction zone; (iii) Removing the vapor product stream and optionally condense it; (iv) Recovering, either together or separately meso-lactide, D-lactide and L-lactide.

A coating composition for providing anti-corrosive, wear-resistance, and sound dampening properties to plastic and metallic substrates. The composition comprises at least one functionalized resin and at least one dry lubricant in a solvent comprising a ketone, and can further comprise at least one of a cross-linking agent, a cross-linking catalyst, a co-solvent, and a colorant. Some compositions comprise multiple ketones and/or multiple dry lubricants, and can be formulated and applied to a substrate without producing hydrogen gas. Substrates coated with the coating composition can include metal components, particularly springs, washers, and other elements, within the liftgate support struts in a van, SUV, or other hatchback vehicle.

A coating composition for providing anti-corrosive, wear-resistance, and sound dampening properties to plastic and metallic substrates. The composition comprises at least one functionalized resin and at least one dry lubricant in a solvent comprising a ketone, and can further comprise at least one of a cross-linking agent, a cross-linking catalyst, a co-solvent, and a colorant. Some compositions comprise multiple ketones and/or multiple dry lubricants, and can be formulated and applied to a substrate without producing hydrogen gas. Substrates coated with the coating composition can include metal components, particularly springs, washers, and other elements, within the liftgate support struts in a van, SUV, or other hatchback vehicle.

A polymer film can be adjusted to movement or a fine uneven surface of a living body and has excellent ability to adhere to a biological tissue. The polymer film includes a block copolymer having a structure in which branched polyalkylene glycol and polyhydroxyalkanoic acid are bound to each other, wherein the polymer film has a film thickness of 10 to 1000 nm. The branched polyalkylene glycol has at least three terminal hydroxyl groups per molecule, the mass percentage of the branched polyalkylene glycol relative to the total mass of the block copolymer is 1% to 30%, and a value obtained by dividing the average molecular weight of polyhydroxyalkanoic acid in the block copolymer by X that is the number of terminal hydroxyl groups present per a single molecule of the branched polyalkylene glycol is 10000 to 30000.

A biopolymer, which exists in a liquid phase at room temperature, a use thereof, and a preparation method therefor are provided.