A delivery device may include a capsule housing, at least one tissue penetrating member in a sealed compartment in the capsule housing, wherein the at least one tissue penetrating member is configured to release a payload, and an actuator in the capsule housing and at least partially outside the sealed compartment, wherein the actuator is configured to advance the at least one tissue penetrating member out of the sealed compartment.

Self-righting articles, such as self-righting capsules for administration to a subject, are generally provided. In some embodiments, the self-righting article may be configured such that the article may orient itself relative to a surface. In some embodiments, the self-righting article may have a particular shape and/or distribution of density (or mass) which, for example, enables the self-righting behavior of the article. In some embodiments, the self-righting article may comprise a tissue interfacing component and/or a pharmaceutical agent. In some cases, upon contact of the tissue with the tissue engaging surface of the article, the self-righting article may be configured to release one or more tissue interfacing components. In some cases, the tissue interfacing component may comprise and/or be associated with the pharmaceutical agent.

Described herein is a drug product delivery device and method of delivering a drug on a swab. The drug product delivery device may include an applicator platform housed within a rigid housing. The applicator platform may be in the form of a plunger. One or more fluidic channels carry fluid from a storage chamber to an applicator. A frangible seal is attached to the plunger between the storage chamber and the applicator. The frangible seal blocks the fluid from moving from the storage chamber into one or more fluidic channels. Actuation of the plunger causes the frangible seal to be ruptured, which causes the fluid to exit the fluid storage chamber and enter into the one or more fluidic channels. The one or more fluidic channels carry the fluid to the applicator.

The present disclosure describes a system for the delivery of therapeutic substances to the cavities of a patient. The system can include a wearable micropump that is fluidically coupled with a handpiece. The handpiece can be inserted, for example, into the middle ear via a surgical tympanotomy approach. The system can enable a controlled injection of a therapeutic substance directly into the patient's cavity.

Devices, systems, and methods for delivering fluid are provided. Devices include a housing configured for intravaginal deployment and retention, at least one reservoir configured to contain a fluid, and a fluid dispensing mechanism configured to dispense the fluid past the cervix and to the uterus of the subject. Methods include intravaginally deploying and retaining a device in the subject, and dispensing the fluid from the device such that the fluid is driven past the cervix to the uterus of the subject.

A drug delivery device having a central axis, the drug delivery device comprising: a first body part; a first attachment part attached to the first body part and having a first distal end; a second attachment part having a second distal end; and an actuator mechanism configured to move the first distal end towards the second distal end.

The present disclosure is in the field of gastroretentive dosage forms. A gastroretentive dosage form for extended retention in a stomach is provided.

Embodiments herein relate to cell encapsulation membranes, devices including the same, and related methods. In an embodiment, a cell encapsulation membrane is included. The cell encapsulation membrane can include a mesh substrate. The mesh substrate can include a first series of fibers extending in a first direction and a second series of fibers extending in a second direction, the first series of fibers intersecting with the second series of fibers, the mesh substrate defining a plurality of apertures disposed between adjacent fibers of the first series and the second series. The cell encapsulation membrane can further include a coating disposed on the mesh substrate, the coating partially occluding the plurality of apertures defined by the mesh substrate and forming pores. Other embodiments are also included herein.

A method for treating tumor cells around a resection cavity comprises positioning a nonconductive material within a resection cavity that is adjacent to a target region. At least a first electrode and a second electrode are positioned relative to the tumor resection cavity so that electric fields between the at least one first electrode and the at least one second electrode travel through the target region. Tumor-treating electric fields are the generated between the at least one first electrode and the at least one second electrode.

Methods of manufacturing tissue interfacing components, such as solid needles comprising one or more therapeutic agents, are disclosed. In some embodiments, a method for manufacturing a tissue interfacing component comprises compressing a granular therapeutic agent within a mold cavity of a mold to form a solid tissue interfacing component. The mold cavity may define an elongated shape extending along a longitudinal axis from an opening of the mold cavity to a distal end of the mold cavity, and the granular therapeutic agent may be compressed by moving a mold punch along the longitudinal axis towards the distal end. After compressing the granular therapeutic agent to form the solid tissue interfacing component, the tissue interfacing component may be removed from the mold and subsequently inserted into tissue to deliver the therapeutic agent to a subject.