The present invention provides a method for selective delivery of a therapeutic or diagnostic agent to a targeted organ or tissue by implanting a biocompatible solid support in the patient being linked to a first binding agent, and administering a second binding agent to the patient linked to the therapeutic or diagnostic agent, such that the therapeutic or diagnostic agent accumulates at the targeted organ or tissue.

Oxygen-sensing materials and methods are disclosed. The materials include oxygen-sensing chromophores embedded in a solid matrix including silk fibroin in an amount by weight of at least 50% of the total weight of the solid matrix. The solid matrix possesses at least partial transparency at relevant wavelengths. The solid matrix is biocompatible and biodegradable. The solid matrix is not a hydrogel. The chromophores are distributed throughout the solid matrix. Tissue oxygenation can be estimated from phosphorescence measurements made from oxygen-sensing materials implanted in subject.

The present invention provides a method for selective delivery of a therapeutic or diagnostic agent to a targeted organ or tissue by implanting a biocompatible solid support in the patient being linked to a first binding agent, and administering a second binding agent to the patient linked to the therapeutic or diagnostic agent, such that the therapeutic or diagnostic agent accumulates at the targeted organ or tissue.

Embodiments described herein relate to compounds for the detection of wounds, e.g., chronic wounds or infected wounds, including compositions, substrates, kits, dressing materials, and articles, and systems containing such compounds. Further embodiments relate to methods of using these compositions, kits and systems in diagnostic assays, and in the diagnosis and/or detection of chronic or infected wounds based on enzymatic conversion of specific substrates which are contained in the compositions. Additional embodiments relate to methods of characterizing wounds based on expression of a plurality of markers and using such information to treat, manage, and follow-up patients suffering from chronic or infected wounds.

The present invention provides an alginic acid-based injectable hydrogel system for labeling an accurate position of a disease lesion and effectively delivering a drug to a target region. The formulation of the present invention can make it easy to locally inject a contrast agent and a drug into a target region while controlling the release rate of the contrast agent or the drug, with the formation of the hydrogel in the injected region. Through the advantages, the labeled position can be accurately determined from images, thereby enhancing the precision of surgical operation, with a minimal incision formed therefor. In addition, when used, the alginic acid-based injectable hydrogel system allows the effective local delivery of a drug to a target region while increasing the long-acting effect of the drug.

A nanosensor-containing polymer composition for the monitoring of physiological parameters and a method for making the composition are disclosed. The composition includes a fluid nanosensor-containing polymer that becomes rigid in the presence of physiological conditions. In the fluid form, the composition can be suitable for injection on to or into the skin. In the rigid form, the nanosensor is substantially immobilized in the polymer. The method includes forming a mixture comprising a nanosensor and polymer precursor(s), subjecting the mixture to conditions suitable for forming the fluid form of the composition; and subjecting the fluid form to physiological conditions to provide a rigid nanosensor-containing composition.

A hydrogel-lightguide based sensory system susceptible to a stimulus signal produced by ambient and stimulating sensory cells embedded in a hydrogel body of the system. Sensory cells generate an optical signal (in response to a user-defined triggering with excitation light or, alternatively, due to bioluminescence) the properties of which, determined based on detection of such signal with an optical detector device, provide characterization of the stimulus and information required for user-defined activation of emitter cells encapsulated in the hydrogel. When activated, emitter cells generate matter and/or light directed to interact with the ambient.

The invention entails methods to detect and at least partially decontaminate an intact skin surface of a person suspected of exposure to harmful substance, such as cholinesterase inhibitors (i.e., nerve agents, carbamate pesticides), vesicants or synthetic opioids. The method uses a two-step film-forming composition, which indicates dermal contact of harmful substances, and at least partially decontaminate the skin surface if needed.

The present invention provides peptide hydrogelators capable of forming hydrogels as carriers of active ingredients and acting as sustained or controlled release drug delivery systems.

Glucose-sensing luminescent dyes, polymers, and sensors are provided. Additionally, systems including the sensors and methods of using these sensors and systems are provided.