Systems and methods for treating tissue including an apparatus that applies or a method involving separating septa to eliminate or reduce the appearance of cellulite or liposuction in combination with separating septa to eliminate or reduce the appearance of cellulite. In one approach, an interventional tool is placed between tissue layers to engage and treat tissue layers between which fat deposits are contained.

A device is configured for use in negative pressure wound therapy (NPWT). The device includes a tube having a tube proximal end and a tube distal end and A coil having a plurality of windings extending from a coil proximal end to a coil distal end. The coil distal end is coupled to the tube proximal end in a manner that enables application of a negative pressure from within the coil through the coil to tissue surrounding the coil. The coil comprises a space between adjacent ones of the plurality of windings, the space having a predetermined dimension.

An aspiration system for aspirating blood clots from a human body has a power source, an aspiration pump, and an electrical motor coupled to the power source and the aspiration pump, wherein the aspiration pump is pulsed at a frequency below 10 Hz.

A method and system for separating a flow of matter is shown and described. The system includes one or more flow separation devices, one or more surgical instruments, and one or more suction sources. In some embodiments, the flow of matter comprises biological material. In some embodiments, the flow of matter comprises surgical waste.

This disclosure includes intraluminal tubes comprising: an elongated tube (e.g., having a proximal portion, a distal portion configured to be disposed inside of an internal cavity of a patient, and a sidewall defining a lumen extending from the proximal portion to the distal portion, the distal portion defining one or more openings in fluid communication with the lumen) and a plurality of deployable tines, each coupled to the tube and disposed outside the sidewall of the distal portion, where each tine is movable from a collapsed state to a deployed state in which a portion of the tine extends laterally away from the distal portion of the tube. In some of the present intraluminal tubes, the sidewall of the distal portion defines a plurality of longitudinal grooves, and each tine is disposed in a different one of the grooves when the tines are in the collapsed state.

An automatic pump-based fluid management system, as described herein, comprises an intercostal pump that is, generally, a resiliently flexible bulb having an inlet and an outlet. The inlet is attached to a first tube that extends from the intercostal pump to a first area of a patient's body, for example, the patient's pleural cavity. The outlet is connected to a second tube that extends from the intercostal pump to a second area of a patient's body, for example, the patient's peritoneal cavity. In use, the intercostal pump is placed between a first rib and a second rib in a patient. The intercostal pump operates by being successively compressed and decompressed between the first and second ribs as the patient breaths.

Ureteral or bladder catheters are provided, including (a) a proximal portion; and (b) a distal portion, the distal portion including a retention portion that includes one or more protected drainage holes, ports or perforations and is configured to establish an outer periphery or protective surface area that inhibits mucosal tissue from occluding the one or more protected drainage holes, ports or perforations upon application of negative pressure through the catheter. Systems, kits and methods for inducing negative pressure to increase renal function also are provided.

Urinary catheter-insertion kits can include a working tray, a storage tray, a urinary catheter, and a drainage system including drainage tubing and a drainage receptacle. The working tray can be configured to nest with the storage tray by suspending the working tray from the storage tray. At least the working tray includes a number of preformed sections configured to hold a number of components of the urinary catheter-insertion kit. At least one section of the preformed sections of the working tray includes a catheter section configured to hold the urinary catheter. The storage tray can be configured to hold the drainage system. Methods of urinary catheterization include use of the urinary catheter-insertion kits.

In one embodiment, a jig apparatus for bending a malleable tool includes a block having an upper surface and containing, a conical recess extending into the block through the upper surface of the block, defined by an elliptical directrix on the upper surface, an apex within the block, and generatrixes disposed about a central axis of the conical recess extending from the apex to the directrix, and an elongated cylindrical hole, which is sized to fit the malleable tool therein and has a longitudinal axis extending from the conical recess into the block at an oblique angle relative to the central axis of the conical recess, and angular markings disposed on the upper surface and around a circumference of the elliptical directrix.

In some examples, a medical aspiration system includes a flow switch configured to passively close to restrict aspiration of a body fluid from a body of a patient. In some examples, the flow switch includes a housing defining an internal cavity, and proximal and distal openings to the internal cavity, where the internal cavity is configured to receive the aspirated fluid from a catheter. The flow switch further includes a plug disposed within the internal cavity and configured to move proximally, in response to an above-threshold drag force from a fluid flow of the aspirated fluid within the internal cavity applied to a distal-facing surface of the plug, in order to close the proximal opening; and move distally to open the proximal opening in response to an absence of the fluid flow within the internal cavity.