A process and system of compatible cannulas with features that are linked and intentionally related including the Interior Cross Sectional Area (302) of the cannulas, the area of the opening(s) of the cannulas and the width of the opening(s) of the cannulas (303). When used in a method where the appropriate harvesting cannula (100) is selected for use with a desired reinjection cannula (100), the cannula kit (FIG. 8) provides increased benefit for maintaining live tissue viability, and minimizes the time of the surgical procedure. The cannula (100) as a kit or set (FIG. 8) is used for harvesting and for reinjection, and serves in extracting, processing and transferring adipose tissue.

A fat cutter and an integrated machine for preparation of in vitro fine-particle fat are provided. The fat cutter includes a fat inlet channel, a fat outlet channel, at least one set of blades disposed between an outlet of the fat inlet channel and an inlet of the fat outlet channel, and a housing that seals a space in which the outlet of the fat inlet channel, the inlet of the fat outlet channel, and the blades are located. A fat inlet of the fat inlet channel is connected to a large-diameter liposuction tube by a liposuction channel, and a fat outlet of the fat outlet channel is connected to a high-negative pressure device. The outlet of the fat inlet channel and the inlet of the fat outlet channel are oppositely provided, and a gap therebetween matches the thickness of the blades.

Methods and devices are disclosed for processing stromal precursor cells (i.e., cells which can differentiate into connective tissue cells, such as in muscles, ligaments, or tendons) which can be obtained from fatty tissue extracts obtained via liposuction. Normal processing of a liposuction extract involves centrifugation, to concentrate the stromal cells into a semi-concentrated form called “spun fat”. That “spun fat” can then be treated by mechanical processing (such as pressure-driven extrusion through 0.5 mm holes) under conditions which can gently pry the stromal cells away from extra-cellular collagen fibers and other debris in the “spun fat”. The extruded mixture is then centrifuged again, to separate a highly-enriched population of stromal cells which is suited for injection back into the patient (along with platelet cells, if desired, to further promote tissue repair or regeneration).

Disclosed is a vessel for recovering adipose tissues including a body sealed by a lid connectable to a first pipe with a suction cannula, and a second pipe with a suction pump. A removable adapter connects a lid including two orifices, each closed by a stopper that can be pierced or is pre-pierced and self-sealing, and a vent opening with a filter and removable plug. The connection adapter includes two rigid piercing tubes projecting from under the adapter, each piercing tube in continuous fluid relationship with a corresponding nipple projecting from the adapter, each nipple connectable to a corresponding pipe. The two sealed orifices of the lid and the adapter and piercing tubes are arranged so, when the connection adapter is applied to the lid, each piercing tube pierces a corresponding stopper and brings each nipple into correspondence, in a sealed manner, with the internal volume of the vessel.

Preparation of a product comprising stromal vascular traction cells includes washing human biological material comprising adipose in a container apparatus having an internal filter, which divides an internal containment volume of the container apparatus into a tissue retention volume on one side of the filter and a filtrate volume on an opposite side of the filter, and a mixing device with at least one rotatable mixing member disposed in the tissue retention volume. The washing includes operation of the mixing device to rotate the mixing member through the human biological material within the tissue retention volume, and the washing is followed by digesting washed material within the internal containment volume with added enzyme, centrifuging of the container apparatus to prepare a centrifuged pellet in the filtrate volume, selectively removing material of the pellet and preparing a product with a mixture of stromal vascular fraction cells of removed pellet material and an aqueous suspension liquid.

Systems, devices, and methods of the present disclosure assist with management of tubes and hoses during surgical procedures. The systems, devices, and methods provide for the proper opening and closing of tubes to facilitate performance of steps in a surgical procedure. Systems, devices, and methods of the present disclosure control fluid delivery to and from a medical device, including devices for tissue processing and cleaning.

A triple-chambered container includes: a main container body with a first chamber which has an opening at its distal end; a main barrel formed and movable longitudinally within the first chamber, the main barrel defining therein a second chamber for receiving fluids, the main barrel further having an apertured stopper at its distal end; a second barrel formed within the main barrel, the second barrel defining a third chamber for receiving fluids, the second barrel being movable longitudinally within and with respect to the main barrel, the second barrel having a distal end which is engageable and disengageable with the apertured stopper; a shaft adapted to fit within the second barrel, the shaft being movable longitudinally within and with respect to the second barrel, the shaft having a distal end which is engageable and disengageable with an aperture in the second barrel; a device for controlling engaging and disengaging of the distal end of the shaft with the aperture of the second barrel. The first chamber, the second chamber and the third chamber may be selectively moved to receive and discharge fluids with respect to one another.

A closed system for harvesting fat through liposuction, concentrating the aspirate so obtained, and then re-injecting the concentrated fat into a patient comprises as its main components a low pressure cannula having between about 7 to 12 side holes of about 1-2 mm by 2.0 to 4.0 mm, a spring loaded syringe holder with a constant force or coiled ribbon spring to apply a substantially constant pressure over the fill excursion of the plunger, and a preferably flexible collection bag which is also preferably graduated, cylindrical over most of its body and funnel shaped at its bottom, all of which are connected through flexible tubings to a multi-port valve. The multi-port valve has two flutter/duck bill valves which restrict the fluid flow to a one way direction which effectively allows the syringe to be used to pump fat out of a patient and into a collection bag in a continuous manner. After the bags are centrifuged to concentrate the fat, the excess fluids are separated and the valve is re-connected to permit the syringe pump to reverse fluid flow to graft the concentrated fat back into the patient.

A device configured to mechanically remove a fat phase from at least one adipose tissue includes a first pressing element and a second pressing element. Furthermore, a method for preparing a preparation including a fat-depleted adipose tissue, comprises mechanically removing a fat phase from at least one adipose tissue. In addition, there is provided a preparation including a fat-depleted adipose tissue, wherein the fat-depleted adipose tissue is prepared by mechanically removing a fat phase from at least one adipose tissue.

Disclosed herein are devices and methods for processing biologic tissues, such as adipose tissue. The devices comprise a rotatable chamber and a fiber collector within. The fiber collector is configured to capture fibers from a sample. The devices further comprise a drive unit configured to rotate the rotatable chamber, thereby producing a centrifugal field, whereupon when a sample of biologic tissue is present in the rotatable chamber, the sample stratifies into at least two constituent layers as a function of the differing specific gravities of the constituents