A device for preparing adipose tissue for transplantation from lobular fat extracted, for instance by liposuction, said fat consisting of a fluid component comprising an oily component, a blood component and/or sterile solutions and a solid component comprising cell fragments, cells and one or more cell macroagglomerates of heterogeneous size, comprising at least one washing and separating container (1) having a washing chamber (101) for washing the liposuctioned material, which container (1) has an inlet (102) and an outlet (103) for the liposuctioned material to enter the washing chamber (101) through the inlet (102) and for at least part of said material, particularly the fluid component, to exit said chamber (101) through the outlet (103), said washing chamber (101) including means for forming an emulsion of fluid components, by mechanical stirring.

A method of preparing adipose tissue for transplantation, from lobular fat extracted, for instance, by liposuction, said fat consisting of a fluid component comprising an oily component, a blood component and/or sterile solutions and of a solid component comprising cell fragments, cells and one or more cell macroagglomerates of heterogeneous size, characterized in that it includes at least one step of washing the cell aggregates carried out at the same time as a step of separating the fluid component, in emulsion form, from the solid component.

A method for capturing dislodged vegetative growth during a surgical procedure is provided. The method includes maneuvering, into a circulatory system, a first cannula having a distal end and an opposing proximal end, such that the first cannula is positioned to capture the vegetative growth en bloc. A second cannula is positioned in fluid communication with the first cannula, such that a distal end of the second cannula is situated in spaced relation to the distal end of the first cannula. A suction force is provided through the distal end of the first cannula so as to capture the vegetative growth. Fluid removed by the suction force is reinfused through the distal end of the second cannula. Subsequent to becoming dislodged, the vegetative growth is captured by the first cannula. A method for capturing a vegetative growth during removal of a pacemaker lead is also provided.

A method for capturing dislodged vegetative growth during a surgical procedure is provided. The method includes maneuvering, into a circulatory system, a first cannula having a distal end and an opposing proximal end, such that the first cannula is positioned to capture the vegetative growth en bloc. A second cannula is positioned in fluid communication with the first cannula, such that a distal end of the second cannula is situated in spaced relation to the distal end of the first cannula. A suction force is provided through the distal end of the first cannula so as to capture the vegetative growth. Fluid removed by the suction force is reinfused through the distal end of the second cannula. Subsequent to becoming dislodged, the vegetative growth is captured by the first cannula. A method for capturing a vegetative growth during removal of a pacemaker lead is also provided.

Disclosed herein are implantable 3-dimensional large capacity device assemblies, specifically, large capacity device assemblies for encapsulating pancreatic progenitor cells for treatment of diabetes.

A macroencapsulation device includes a frame, a first membrane layer, a second membrane layer disposed on the first membrane layer, and an interior volume between the first and second membrane layers. The interior volume can encapsulate a population of cells. The frame includes a fill port extending from an exterior of the frame to an interior of the frame, with two slots formed in the frame on opposing sides of the fill port. The slots are formed on an interior portion of the frame. The first and second membrane layers are bonded together by a seal, which extends around and defines part of a perimeter of the interior volume. The seal includes two projections disposed in the two slots of the frame. A method of manufacturing includes bonding two membrane layers to form a seal defining a perimeter of an interior volume, and inserting the projections into the slots.

A method of delivering cells to a target tissue is provided comprising depositing a hydrogel pre-gel comprising magnetic particle-loaded cells to the target tissue and, prior to or during gelation of the hydrogel, drawing the magnetic particle-loaded cells to the tissue with a magnetic field, followed by gelation of the hydrogel to lock the cells in place on the tissue. The cells may be mesenchymal stem cells, such as adipose-derived mesenchymal stem cells, and the target tissue may be adventitial tissue of an aneurysm in a blood vessel. Also provided are devices useful in the method.

A system may include a donor supply sub-system configured to supply donor material to a donor substrate. The system may include a material transfer sub-system comprising a laser configured to illuminate the donor substrate via a transfer beam. The system may include an instrument head of a medical instrument configured to house the donor substrate, wherein upon an illumination of the donor substrate, the donor material is transferred to receiver material in vivo.

Provided herein are devices, systems, and methods for subcutaneous membrane, encapsulation chamber, or reservoir implantation comprising or employing an implantation device configured to insert a membrane, encapsulation chamber, or reservoir into a subject.

A system and method for harvesting autologous tissue, mincing it into fragments that are visible and measurable when filtered, and delivering a portion of the tissue back into the patient without the need to directly touch the tissue. During the same surgical procedure, the tissue can be mixed with a biocompatible agent before introduction into the repair site.