Implantable devices comprising a scaffold, cells, and/or therapeutic molecules are provided. Uses include inhibition of pathological immunity, elaboration of therapeutic growth factors, and immune augmentation. The implantable device may contain a porous substrate structure to which therapeutic cells are adherent, which can be implanted and explanted from a patient. In another embodiment, a medical device includes a porous substrate seeded with therapeutic cells, said device comprising of an additional layer allowing free exchange of molecules without cell escape. Said medical device is seeded with thymic medullary epithelial cells or progenitors of said thymic medullary epithelial cells. In conditions where tolerance to alloreactive donor cells is desired, the thymic medullary epithelial cells or progenitors thereof are derived from recipient cells. In conditions where tolerance to alloreactive recipient cells is desired, the thymic medullary epithelial cells or progenitors thereof are derived from donor cells.

The invention relates to a modular irradiation device having a main module and at least one support cassette, the support cassette being insertable into a receptacle of the main module. The support cassette has at least one pump, and the main module has at least one pump actuator, these being arranged such that the pump is actuatable with the pump actuator when the support cassette is inserted into the receptacle of the main module.

The present disclosure provides methods of obtaining, recovering and culturing pulmonary arterial endothelial cells from an individual patient subjected to a right heart catheterization in regard to diagnosis of pulmonary hypertension. These isolated pulmonary arterial endothelial cells from an individual patient may be utilized to generate cellular phenotyping profile for the cell population, allowing generation of a personalized pharmacotherapy regime to assist the clinician in treatment and prognosis of the disorder for an individual patient.

Disclosed herein is a method of preparing a subject's cells for topical treatment of a subject in need. Also provided is a topical formulation and methods of treating a subject suffering a skin disorder and pain using the topical formulation. Also disclosed herein are devices and systems for micronizing an aspirate in preparation of such a topical formulation.

A method of non-thermally ablating undesirable tissue in the body by application of pulsed, bipolar, instant charge reversal electrical fields of sufficient energy to cause complete and immediate cell membrane rupture and destruction. Energy is delivered through radio frequency pulses of particular frequencies, wave characteristics, pulse widths and pulse numbers, such that enhanced physical stresses are placed on the cell membrane to cause its immediate and complete destruction thereby spilling the entire cell content and membrane constituents into, the extracellular space without denaturing proteins so as to enable an immuno-logical response to destroy and remove the target tissue and similarly marked tissue elsewhere in the subject.

The invention is a microneedle preparation administration apparatus comprising: a guide tube; a pedestal in which at least a part thereof including a front end surface is housed within the guide tube and slides in length direction; and driving means for driving the pedestal toward a front end part of the guide tube, and microneedle preparations being to be attached to the front end surface of the pedestal.

An implantable containment apparatus for receiving and retaining a plurality of cells for insertion into a patient, such as into a tissue bed, is disclosed. The device includes a chamber having structural spacers therein to maintain an average distance between the first interior surface and the second interior surface of the chamber and to define at least one reservoir space for the placement of cells within the chamber.

Disclosed herein are devices for micronizing an aspirate. Also disclosed herein are systems for micronizing an aspirate. The devices and systems may include a liposuction syringe for liquefying fat and/or an incubator for expansion of cells. Devices and systems may also include a handpiece with a handle, a motor disposed within the handle, a blade positionable within a syringe barrel containing an aspirate, the blade rotationally coupled to the motor by a drive shaft, and an end cap positioned along the drive shaft between the blade and the handle, the end cap including an opening through which the drive shaft extends, the end cap configured to seal the syringe barrel.

An implantable containment apparatus for receiving and retaining a plurality of cells for insertion into a patient, such as into a tissue bed, is disclosed. The device includes a chamber having structural spacers therein to maintain an average distance between the first interior surface and the second interior surface of the chamber and to define at least one reservoir space for the placement of cells within the chamber.

The present disclosure provides methods of obtaining, recovering and culturing pulmonary arterial endothelial cells from an individual patient subjected to a right heart catheterization in regard to diagnosis of pulmonary hypertension. These isolated pulmonary arterial endothelial cells from an individual patient may be utilized to generate cellular phenotyping profile for the cell population, allowing generation of a personalized pharmacotherapy regime to assist the clinician in treatment and prognosis of the disorder for an individual patient.