A bone fixation device made of polysaccharide particles or microspheres fused into a solid structure is provided herein. The bone fixation device may be in the form of an orthopedic screw, orthopedic pin, or orthopedic plate. Methods of making the bone fixation devices described herein are provided as are methods of treating patients in need of bone repair or replacement by implanting a bone fixation device described herein in the patient at a site of bone damage, ligament damage, or bone deformity.

An extrudable hydrogel composition useful for making a three-dimensional organ construct includes a cross-linkable prepolymer, a post-deposition crosslinking group, optionally, an initiator that catalyzes the reaction between the prepolymer and said the crosslinking group; live cells (e.g., plant, animal, or microbial cells), optionally at least one one growth factor, and optionally water to balance. Methods of using the same and products so made are also described.

Methods for making an osteoimplant are provided. In one embodiment the method includes applying a mechanical force to an aqueous slurry of insoluble collagen fibers to entangle the insoluble collagen fibers so as to form a semi-solid mass of entangled insoluble collagen fibers; and lyophilizing the semi-solid mass of entangled collagen fibers to form the osteoimplant. An osteoimplant containing entangled insoluble collagen fibers is also provided.

This invention relates to a water-soluble film (WSF) system with embedded/entrapped water-soluble films (WSF). More particularly, the invention relates to a WSF system with actives embedded/entrapped therein such as to provide precise and desired release of actives there from and its method of manufacturing for diverse applications, in which a variety of substances such as detergents, enzymes, softeners, perfumes, pesticides, fungicides, active ingredients, dyes, pigments, hazardous chemicals, active agents for cleaning laundry, dishes, floorings, walls, furniture, fluffs, pulp, etc., and the like can be so embedded/entrapped for such purpose. The invention further discloses novel online and offline process for the manufacture of such multi-layered WSF with or without liners and of desired shapes to selectively entrap interacting/non-interacting materials and their combinations. The process also provides options for the use of a wide range of raw materials, liners such as paper, film, foil, fabric, etc.

Provided are a hydrogel composition with high viscoelasticity and a bioink composition including the hydrogel composition. The hydrogel composition according to an embodiment is composed of natural biocompatible substances and thus is not toxic, but has high viscosity, resulting in high mechanical stability or long persistence. Thus, the hydrogel composition may be usefully utilized as a bioink composition for bioprinting, a support in tissue engineering, or a soft tissue filler.

The present disclosure relates to a solid hair cosmetic composition comprising—based on the total weight of the cosmetic composition—about 30.0 to about 60.0% by weight of at least one polyhydric alcohol, and optionally: about 0.1 to about 15.0% by weight of at least one cationic surfactant, about 0.1 to about 20.0% by weight of at least one saturated or unsaturated, branched or unbranched C.sub.8-C.sub.30 alcohol and/or a saturated or unsaturated, branched or unbranched C.sub.8-C.sub.30 carboxylic acid and/or a salt of a saturated or unsaturated, branched or unbranched C.sub.8-C.sub.30 carboxylic acid, and about 0.1 to about 40.0% by weight of at least one polysaccharide, as well as production and application methods and uses thereof.

A strip-form toilet cleaning product comprising a width (B), a height (H) and a thickness (S), wherein the ratio between width (B), height (H) and thickness (S) is between 1:1:0.01 and 1:0.1:0.2, a first extruded phase and at least one second extruded phase, wherein at least the contour of a contact surface (4, 4a, 4b) along the center axis (8) takes the form of a sine wave which has an amplitude of A.sub.1,O, wherein the ratio of amplitude to width (B) A.sub.1,O:B amounts to between 1:10 and 1:25 and the periodic length of the sine wave corresponds to 0.1-1 times the width (B) of the toilet cleaning product.

A microneedle chip and manufacturing method. The method comprises injecting, into a female mold, a fluid needle liquid, wherein forming cavities matching the shapes of needles of a microneedle chip are provided at the female mold and form a cavity array, injection inlets are provided at a surface of one side of the female mold, and air ejection openings are provided at a surface of another side of the female mold to form an air ejection surface; covering the air ejection surface of the female mold using a breathable film, and during injection, passing a gas through the breathable film so as to retain the liquid inside the forming cavities; curing the fluid needle liquid to form the microneedle chip, and demolding to obtain the same. By employing the air ejection openings and the breathable film, a liquid is retained while ejecting a gas, providing a favorable micro-injection effect.

A manufacturing method for a micro-needle device includes following steps: a target tissue basic information obtaining step, a micro-needle template obtaining step, a micro-needle material adding step, a micro-needle semi-product obtaining step, and a micro-needle device obtaining step. The inner tissue distribution information is obtained by the application of optical coherence tomography. The micro-needle template is obtained according to the skin surface curvature information and the inner tissue distribution information. The micro-needle template has a plurality of areas and a plurality of mold holes. One or both of the diameter and the depth of the mold hole is determined by the inner tissue distribution information, and the curvature radius of the areas is determined by the skin surface curvature information. The manufacturing method for a micro-needle device is applicable to micro-needles with mixed configurations as well as micro-needles with syringe configurations.

Disclosed are systems, compositions, and methods for three-dimensional (3D) printing. An example system includes a plurality dispensers configured to deposit materials from their tips and a printing surface for receiving the materials. The system includes a position sensing detector configured to detect positions of the tips of the dispensers and the location and dimensions of the printing surface. The system includes a robotic positioning device configured to drive the dispensers. The system also includes a control unit configured to receive and map in a 3D space the positions of the tips of the dispensers and the position and dimensions of the printing surface. The control unit is further configured to control the robotic positioning device to drive the dispensers relative to the printing surface in the 3D space, and to independently deposit materials on the printing surface, or on material deposited on the printing surface.