Disclosed in certain embodiments is a solid oral dosage form comprising a heat-labile gelling agent; a thermal stabilizer; and a drug susceptible to abuse.

Disclosed in certain embodiments is a solid oral dosage form comprising a heat-labile gelling agent; a thermal stabilizer; and a drug susceptible to abuse.

A wound covering is provided that comprises a substrate and vitamin D, or analogues or metabolites thereof, embedded in the substrate. Methods of making a wound covering are also provided and include the steps of providing a solution that includes a polymer; adding vitamin D, or analogues or metabolites thereof, to the solution to form a mixture; and forming one or more fibers from the mixture that are then embedded with the vitamin D, or analogues or metabolites thereof. Methods of treating a subject are further provided and include the step of applying a wound covering including one or more fibers embedded with vitamin D, or analogues or metabolites thereof, to a site on a subject.

The present disclosure relates to, inter alia, methods of treating mixed dyslipidemia with ethyl eicosapentaenoate.

The present disclosure relates to, inter alia, methods of treating mixed dyslipidemia with ethyl eicosapentaenoate.

Protein complex variants, compositions, and methods of use thereof are provided. The protein complex variant includes a cholera toxin B subunit variant having one or more modifications thereto. The method of use thereof includes treating a disease by administering an effective amount of a composition including a cholera toxin B subunit variant to a subject in need thereof.

Provided herein are antioxidant, thermally-responsive copolymer-based compositions and methods of making and using the compositions, e.g., for treatment of ischemia reperfusion injury in a patient. The copolymer comprises a hydrocarbyl backbone, and a plurality of pendant pyrrolidone, antioxidant radical, polyester oligomer, and N-alkyl amide groups.

The present disclosure is directed to formulations and methods for treatment of disease such as chemoprevention of cancer, for example oral squamous cell carcinoma (OSCC), and for methods of preparing the formulations. Further, the disclosure relates to local administration in slow release dosage forms for treatment of disease. The extended-release formulations are comprised of biodegradable polymeric implants (for example millicylinders and microspheres as well as in situ forming gels) and therapeutic agents selected from an anti-interleukin 6 agent, a synthetic vitamin A analogue and/or metabolite, and/or an estradiol metabolite for the local delivery of therapeutic agents to a site where a cancer has been previously excised or to prevent progression of a precancerous lesion.

The present disclosure is directed to formulations and methods for treatment of disease such as chemoprevention of cancer, for example oral squamous cell carcinoma (OSCC), and for methods of preparing the formulations. Further, the disclosure relates to local administration in slow release dosage forms for treatment of disease. The extended-release formulations are comprised of biodegradable polymeric implants (for example millicylinders and microspheres as well as in situ forming gels) and therapeutic agents selected from an anti-interleukin 6 agent, a synthetic vitamin A analogue and/or metabolite, and/or an estradiol metabolite for the local delivery of therapeutic agents to a site where a cancer has been previously excised or to prevent progression of a precancerous lesion.

Disclosed herein are fully synthetic polymer-based lung surfactant materials, for the first time, as next generation SRT. In vitro studies on these polymer lung surfactants show that the candidate materials effectively mimic the surface tension controlling properties of currently marketed natural lung surfactants. Further, the polymer lung surfactants have strong protein resistance, which makes this class of materials promising also for potential use in Acute Respiratory Distress Syndrome (ARDS) treatment.