The present disclosure relates to microneedle devices and methods for treating a disease (for example, diabetes) using a degradable cross-linked gel for self-regulated delivery of a therapeutic agent (for example, insulin).

Three-dimensional printed antibiotic scaffolds are provided as well as methods of use thereof and methods of making.

The present disclosure relates to microneedle devices and methods for treating a disease (for example, diabetes) using a degradable cross-linked gel for self-regulated delivery of a therapeutic agent (for example, insulin).

A composition comprising a bioresponsive (e.g., reactive oxygen species (ROS)-responsive), antibiotic- and/or absorbent-loaded polymeric network is described. In some cases, the composition can release the antibiotic loaded therein in response to ROS or another stimulus related to inflammation. Microneedles, microneedle arrays, and skin patches comprising the composition are also described, as well as methods of treating acne or other inflammatory/infectious skin conditions.

The present application provides an organosilica nanoparticle comprising: (a) a photosensitizer for photodynamic therapy covalently incorporated therein; and (b) optionally, at least one agent encapsulated therein, as well as a pharmaceutical composition comprising said organosilica nanoparticle. Also provided herein are said organosilica nanoparticle or pharmaceutical composition for use as a medicament or in the treatment of a disease, disorder, or condition. More specifically, provided is a method for treating a disease, disorder, or condition in a subject using said aid organosilica nanoparticle or pharmaceutical composition.

Disclosed herein are small mobile stem (SMS) cells and methods of culturing, isolating, and using SMS cells. Also disclosed are methods of culturing SMS cells in an undifferentiated state for prolonged periods of time, and for using SMS cells for the production of a variety of molecules, including proteins, extracellular matrix (ECM) proteins, and the use of SMS cells in microfluidic devices.

The present disclosure relates to microneedle devices and methods for treating a disease (for example, diabetes) using a degradable cross-linked gel for self-regulated delivery of a therapeutic agent (for example, insulin).

A system for delivering a therapeutic dose of a drug is disclosed. The system includes a delivery medium with therapeutic units attached thereto. The delivery medium is preferably a polymeric hydrogel matrix that has therapeutic units incorporated therein or metal nanoparticles with therapeutic units complexed thereto. The therapeutic units include nucleic acid moieties. The nucleic acid moieties preferably include strands of nucleic acid and drug moieties complexed with the strands of nucleic acid. Where the system includes a polymeric hydrogel matrix, an active drug is controllably released from the polymer hydrogel matrix to provide a therapeutic dose to a biological system or biological tissue. The active drug is controllably released from the hydrogel matrix by altering the environment the hydrogel matrix, or by enzymatic cleavage of the nucleic acid moieties or by a combination thereof.

A plant extract, derived from a Salvia spp, may include one of at least one tanshinone compound, or at least one tanshinone compounds including a CYP11B1 inhibitory amount of at least one of tanshinone I and dihydrotanshinone. The plant extract may be used for use in the treatment of a wound or Cushing's syndrome.

Disclosed herein are small mobile stem (SMS) cells and methods of culturing, isolating, and using SMS cells. Also disclosed are methods of culturing SMS cells in an undifferentiated state for prolonged periods of time, and for using SMS cells for the production of a variety of molecules, including proteins, extracellular matrix (ECM) proteins, and the use of SMS cells in microfluidic devices.