A transdermal therapeutic system for administering at least one active pharmaceutical ingredient, including a polymer-based layer which is remote from the skin with a rate of application of at least 80 g/m.sup.2, and an adhesive skin-contact layer which is adjacent to the polymer-based layer remote from the skin and is based on acrylate copolymers with a rate of application of not more than 50 g/m.sup.2. The at least one active pharmaceutical ingredient is present in both the polymer-based layer remote from the skin and the skin-contact layer.

A method of forming an implantable article includes providing a biodegradable polymer including anti-thrombogenic groups along the length of the biodegradable polymer, biodegradable groups in the backbone of the biodegradable polymer and a plurality of functional groups adapted to react with reactive functional groups on a surface of the implantable article, and reacting at least a portion of the plurality of functional groups with the reactive functional groups on the surface of the implantable article.

The present invention relates to a filler comprising a hyaluronic acid hydrogel having a lift value in a specific range relative to the unit amount (w/w %) of hyaluronic acid included in a filler, in contrast to the modification degree, and as a result of having said lift value the filler exhibits improved high viscoelasticity flow properties, has the advantages of both monophasic and biphasic hyaluronic acid hydrogel fillers, and thus exhibits good tissue-restoring properties, has low mobility when injected into skin whilst still maintaining the shape thereof for a long time, and has minimized deformation of the hyaluronic acid through the minimization of the use of crosslinkers, and thus the natural form of hyaluronic acid molecules can be maintained, enabling a reduction in the occurrence of immune reactions and side effects, and thus has excellent soft tissue restoration properties, volume expansion properties and wrinkle alleviation properties.

A composition for wound healing, comprising an amount of a macrophage proresolving polarizer, wherein the amount is effective to promote wound healing. The composition includes wherein the macrophage proresolving polarizer is lipin-1. The composition includes wherein the composition includes one, two, or three of IL-4, apoptotic cells (ACs), and AC derived lipids. The composition includes wherein the macrophage proresolving polarizer is a lipin-1 transcriptional coregulatory activity promoter. The composition includes, wherein the lipin-1 transcriptional coregulatory activity promoter is an inhibitor of lipin-1 macrophage pro-inflammatory responses enzymatic activity. A method for promoting wound healing, comprising contacting a wound on a skin of a mammal with the composition. A kit comprising one or more containers including the composition in sterile packaging. A wound healing device comprising a substrate and an amount of an amount of a macrophage proresolving polarizer, wherein the amount is effective to promote wound healing.

A composite medical textile such as a suture includes a plurality of bioresorbable hyaluronan-based fibers and a plurality of non-resorbable fibers. The hyaluronan-based fibers can include at least one of hyaluronic acid, sodium hyaluronate, or the esters of hyaluronic acid such as the benzyl esters. The non-resorbable fibers can be Ultra High Molecular Weight Polyethylene (UHMWPE), and other materials. Methods of making a medical textile are also disclosed.

The present invention relates to a process for depleting epoxide species in epoxy-crosslinked polysaccharide gel compositions. In addition, the present invention relates to crosslinked polysaccharide gel compositions made by said process and their use in cosmetic and therapeutic applications.

The present technology relates to depots for the treatment of postoperative pain via sustained, controlled release of a therapeutic agent. In some embodiments, the depot may comprise a therapeutic region comprising an analgesic, and a control region comprising a bioresorbable polymer and a releasing agent mixed with the polymer. The releasing agent may be configured to dissolve when the depot is placed in vivo to form diffusion openings in the control region. The depot may be configured to be implanted at a treatment site in vivo and, while implanted, release the therapeutic agent at the treatment site for no less than 3 days.

Disclosed herein is a biomaterial and a method of use thereof for treating a condition. A biomaterial of the disclosure can be, for example, a surgical article. Implantation of a biomaterial disclosed herein into a subject can treat, for example, cancer.

Disclosed are a sustained-release injection formulation containing a biodegradable polymer double microcapsule that contains a conjugate of poly-L-lactic acid (hereinafter referred to as “PLLA”) filler and hyaluronic acid (hereinafter referred to as “HA”) and is capable of controlling the release rate of PLLA, and a method of preparing the same.

The present invention relates to a formulation sized for injection comprising a biodegradable polyesteramide co-polymer comprising at least a diol of bicyclic-1,4:3,6-dianhydrohexitol and analgesics for use in the treatment of arthritic disorders. More specific the invention relates to a formulation comprising injectable microparticle according to claim 1 wherein the polyesteramide co-polymer further comprises a diacid, a diol different from bicyclic-1,4:3,6-dianhydrohexitol and at least two different amino-acids. The formulation is used to treat pain or inflammation in a patient comprising administering to said patient a therapeutically effective amount of the formulation once or twice a year.