The invention relates to a method for producing a storable molded body made of bacterial cellulose and a molded body produced according to the method. A preferred method includes providing a molded body made of bacterial cellulose. Optionally, mechanically pressing the entire molded body or parts of the molded body at temperatures in the range of 10° C. to 100° C. and pressures in the range of 0.01 to 1 MPa for a pressing time of 10-200 min. Treating the molded body with a solution of 20% by weight to 50% by weight of glycerol and 50% by weight to 80% by weight of a C1-C3-alcohol/water mixture. Drying the treated molded body.

A barrier layer and corresponding method of making provide anti-inflammatory, non-inflammatory, and anti-adhesion functionality for a medical device implantable in a patient. The barrier layer can be combined with a medical device structure to provide anti-adhesion characteristics, in addition to improved healing, non-inflammatory, and anti-inflammatory response. The barrier layer is generally formed of a naturally occurring oil, or an oil composition formed in part of a naturally occurring oil, that is at least partially cured forming a cross-linked gel. In addition, the oil composition can include a therapeutic agent component, such as a drug or other bioactive agent.

A solid drug core insert can be manufactured by injecting a liquid mixture comprising a therapeutic agent and a matrix precursor into a sheath body. The injection can be conducted at subambient temperatures. The mixture is cured to form a solid drug-matrix core. The therapeutic agent can be a liquid at about room temperature that forms a dispersion of droplets in the matrix material. A surface of the solid drug core is exposed, for example by cutting the tube, and the exposed surface of the solid drug core releases therapeutic quantities of the therapeutic agent when implanted into the patient. In some embodiments, the insert body inhibits release of the therapeutic agent, for example with a material substantially impermeable to the therapeutic agent, such that the therapeutic quantities are released through the exposed surface, thereby avoiding release of the therapeutic agent to non-target tissues.

Biologically activated ion-exchange polymer salts are made by exchanging biologically active ionic agents onto ion-exchange polymers. The activated polymers are uniquely surface active and stable to thermal degradation and chemical and other forms of decomposition. The activated ion-exchange polymer salts may be processed and combined with polymer precursors using novel methods and materials to produce stable, biologically activated polymer composites, including antimicrobial and antifouling polymer composites.

Disclosed is 1) a method for greatly increasing the solubility of useful actives in siloxane matrix-forming preparations, and 2) the associated preparations, themselves. Volatilizing coagents are utilized to give novel gels containing heretofore siloxane-insoluble additives.

Methods for detecting, imaging, analyzing, diagnosing and/or treating cutaneous conditions and dermatoses such as disorders of the skin, subcutaneous tissues, mucous membranes, poorly vascularized tissues and/or other tissue disorders, including erosions, fissures, transient and/or chronic sores, burns, wounds, ulcers, lesions and infections. In particular embodiments, treatments include methods for improving skin and related tissue healing and repair, offloading of damaged tissues and/or increasing angiogenesis in response to specifically diagnosed conditions.

The present invention relates to a peptide that binds specifically to the surface of zirconia, and more particularly, to a peptide conjugate obtained by linking a functional drug to the peptide so as to enable the drug to be securely fixed to the surface of zirconia to thereby maintain the activity of the drug over a long period of time. The zirconia-binding peptide according to the present invention can be securely fixed to the surface of zirconia so that the activity of a physiologically active substance introduced into the peptide can be maintained on the zirconia surface over a long period of time. Thus, the zirconia-binding peptide is useful for surgical regenerative treatment.

This disclosure relates to dermal treatment compositions, such as dermal fillers and tissue glues, and injectable compositions that incorporate one or more cationic steroidal antimicrobials (CSAs). The CSAs are incorporated into the dermal treatment compositions to provide effective antimicrobial, anti-inflammatory, analgesic, anti-swelling and/or tissue-healing properties. A treatment composition includes a component formed from a biologically compatible material suitable for injection into and/or application onto tissue at a treatment site. One or more CSA compounds are mixed with the biologically compatible material so that the one or more CSA compounds are incorporated within the composition, forming a reservoir of CSA compounds within the resulting bolus of the treatment composition after injection and/or application.

Implants and methods for treating ocular disorders are provided. One method involves introducing an implant into an anterior chamber of an eye. The implant is implanted into eye tissue adjacent the anterior chamber such that a proximal end of the implant resides in the anterior chamber following implantation. A therapeutic agent is eluted from the implant into the eye. Desirably, the release of the therapeutic agent from the implant is controlled. The controlled release of the therapeutic agent can be at a chosen rate and/or for a selected duration which can be episodic or periodic. The therapeutic agent can be an antiproliferative agent, an anti-inflammatory drug, or a compound for treating glaucoma or ocular hypertension.

A mixture for an injectable scaffold may include a self-assembling core and an additive. The additive may include an angiogenic agent, a small molecule drug, and/or an anti-inflammatory agent. The scaffold can be applied to sites where bone growth is desired.