A fat conditioning apparatus includes a conditioning vessel enclosing a conditioning chamber and a displacable plug. The conditioning chamber is bounded on one end by the displacable plug and has a variable volume that is a function of the position of the plug within the conditioning vessel. The apparatus has utility in a fat conditioning method, wherein the conditioning chamber contains a harvested fat emulsion. A washing liquid is injected into the conditioning chamber and mixes with the harvested fat emulsion, thereby displacing the plug in an outward expansion direction and expanding the variable volume of the conditioning chamber. The resulting mixture of harvested fat emulsion and washing liquid is stratified in the conditioning chamber into a contaminant-lean fat fraction and a contaminant-rich remainder fraction. The fat fraction, which is substantially free of the remainder fraction, is recovered from the conditioning chamber as a desired product of the method.

A plunger locking assembly is provided for a syringe which has a barrel and a plunger. The barrel has a closed end with a cannula connector, an open end bounded by a peripheral lip and a barrel longitudinal axis extending between the closed end and the open end. The plunger has a plunger inner end, a plunger outer end and a plunger longitudinal axis extending between the plunger inner end and the plunger outer end. The plunger is slidably displacable within the barrel to different longitudinal lock positions and the barrel and plunger longitudinal axes are coextensive with one another. The plunger locking assembly includes a main body and a plunger locking mechanism. The main body has an inner end, an outer end and a main body longitudinal axis and is adapted to engage the plunger. The plunger locking mechanism is positioned on the main body and is adapted to lock the plunger at a fixed longitudinal lock position within the barrel to prevent further slidable displacement of the plunger into the barrel.

Provided herein are devices useful in processing fat for fat grafting and for delivering fat tissue grafts to a patient. Also provided are devices and methods for fat grafting and for treatment of plantar fasciitis.

A catheter for atraumatic delivery of fluid is disclosed. In embodiments, the catheter includes a catheter shaft with a guidewire lumen disposed within the catheter shaft and an infusion lumen at least partially defined by the catheter shaft. The infusion lumen may at least partially surround the guidewire lumen. The catheter shaft includes a plurality of pores extending through an outer surface of the catheter shaft to the infusion lumen. The plurality of pores are disposed near a distal end of the catheter shaft and are configured to radially dispense a fluid from the infusion lumen.

The present disclosure provides devices and methods for processing and harvesting adipose tissue. The present disclosure provides improved devices, systems, and methods for harvesting, processing, and filtering adipose tissue for autologous fat transfer procedures. The features of the devices and systems of the present disclosure increase efficiency and sterility of adipose tissue processing by reducing the need for users to interrupt the procedure to adjust some part of the system, such as unclogging filter pores or adjusting tubing.

In an illustrative embodiment, a surgical system is provided for removing adipose buildup from epidural space of a patient spine including a surgical apparatus including a handle portion and a catheter assembly having a steerable distal tip configured for navigating epidural space of the spine; an endoscopic camera system configured to capture images from the epidural space and to identify a tissue of interest; and a vacuum source in communication with the catheter assembly of the surgical apparatus and configured to provide a negative pressure through a lumen of the catheter assembly to the tissue of interest; a discharge tank configured to capture suctioned tissue from the catheter assembly; and where the surgical apparatus further includes at least one fiber optic cable in communication with the endoscopic camera system.

A method for removing fat from salvaged blood includes transferring salvaged blood from a reservoir to a blood component separation device, and separating the blood into a plurality of blood components. The method may then transfer a volume of unwashed blood components from the blood component separation device back toward the reservoir, and re-centrifuge the blood components remaining within the blood component separation device. After re-centrifuging, the method transfers additional salvaged blood from the reservoir to the blood component separation device to refill the blood component separation device. The method may then wash the components within the bowl by introducing wash solution into the blood component separation device. The wash solution displaces a volume of fat from the blood component separation device and into a waste container. The method may then empty the washed blood components within the blood component separation device to a product container.

Disclosed herein a liposuction cannula that comprises a tube with a front end at which there is provided at least one suction opening, and with a back end intended to be connected to a source of vacuum; in the tube there being defined at least one longitudinal flow conduit for the aspirated material; and an imaging apparatus capable of supplying first signals or data allowing the generation of a visual representation of the environment in close proximity to the front end of the tube of the cannula down to a first depth or distance, and second signals or data allowing the generation of a visual representation of the environment around the front end of the tube of the cannula down to a second depth or distance, greater than the said first depth or distance.

Systems, instruments, and methods for minimally invasive procedures including one or more of fractional resection, fractional lipectomy, fractional skin grafting, fractional scar revision, and/or fractional tattoo removal are described. Embodiments include instrumentation comprising a scalpet assembly coupled to a carrier, and the scalpet assembly includes a scalpet array. The scalpet array includes one or more scalpets configured for fractional resection, fractional lipectomy, fractional skin grafting, fractional scar revision, and/or fractional tattoo removal. The system includes a vacuum component coupled to the scalpet assembly and configured to evacuate tissue from the a site. The carrier is configured to control application of a rotational force and/or a vacuum force to the scalpet assembly.

Systems, devices and methods for use in liposuction and infusion medical procedures including handheld devices, micro-cannulas, curved cannulas vacuum pressure changing features.