A system and apparatus for the collection of serous or serosanguinous fluid from a percutaneous site after surgery. A pump unit with one or more pumps or powered sources provide continuous negative pressure suction to draw fluid from the percutaneous site and pumps the fluid into disposable reservoirs with one-way valves that are easy to handle while maintaining sterility and a seal to prevent the loss of vacuum. Air is continuously removed from the reservoirs. Measurement and analysis of the output is performed automatically. Additionally, through such a peristaltic pump device, controlled collection of measured surgical and/or bodily fluid from a subject patient may be undertaken allowing for more effective and closer analysis, as well.

A system and apparatus for the collection of serous or serosanguinous fluid from a percutaneous site after surgery. A pump unit with one or more pumps or powered sources provide continuous negative pressure suction to draw fluid from the percutaneous site and pumps the fluid into disposable reservoirs with one-way valves that are easy to handle while maintaining sterility and a seal to prevent the loss of vacuum. Air is continuously removed from the reservoirs. Measurement and analysis of the output is performed automatically.

A method of analyzing fluid collected from a wound site, the method comprising the steps of: (a) providing a pump unit comprising: one or more pumps, one or more fluid collectors, and one or more drainage structures each in communication with an exit site of the wound site to draw the fluid through the one or more drainage structures into the pump unit and create a negative pressure at the exit site to remove and transport the fluid from the exit site and into the one or more fluid collectors, wherein the pump unit is configured to create a negative pressure, wherein the fluid removal from the exit site is provided at a controlled and measured rate; b) collecting the fluid within the one or more fluid collectors; c) removing the one or more fluid collectors; e) capping the one or more fluid collectors with a cap; and d) analyzing the collected fluid of step “b” once the fluid connectors are removed in step “c”.

A shunt for draining fluid including a first catheter, an electronic pump fluidly coupled to the first catheter, a manual pump fluidly coupled to the electronic pump, a second catheter fluidly coupled to the manual pump. During a drainage operation, the shunt arranged and configured such that a fluid is passively pressure-driven through the shunt, and the electronic pump is arranged to prevent blockages within the shunt by flowing a bolus of the fluid through the shunt. Additionally, the manual pump is arranged to prevent blockages within the shunt by flowing a bolus of the fluid through the shunt in the event that the electronic pump cannot produce a bolus of the fluid.

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.

Embodiments disclosed herein are directed to a drainage system for draining a fluid from a patient where the system includes a drainage tube that provides fluid communication between a catheter and a collection container. The drainage tube includes a port and a balloon attached to an interior of the drainage tube, where the balloon is configured to receive air from a needle that has pierced the port and occlude a lumen of the drainage tube. When in an inflated state, the balloon occludes the lumen of the drainage tube thereby breaking the fluid communication between the catheter and the collection container and preventing the output airflow device from drawing airflow out of the catheter. The balloon may be attached to the interior of the drainage tube by surrounding an interior side of the port.

Disclosed herein is an automated urinary output monitoring system including urine collection assembly that includes a first drainage tube coupled between a urinary catheter and an interim container, and a second drainage coupled between the interim container and a final container. A scale measures the weight of urine collected in the final container and a display depicts the volume of urine collected in the final container. A vacuum pump can be coupled with the final container to draw urine from the interim container into the final container, and an air vent can isolate the patient from the vacuum within the final container. The system can be configured to wirelessly transmit urine volume data to an external computing device. A gyroscope can be coupled with the scale to determine the orientation of the scale. Logic of the system can calculate urine volume and correlate with the time of day.

Various forms of anti-clog suction tips apparatus are disclosed. An exemplary anti-clog suction tip apparatus includes a suction tip assembly having a suction tip with a suction opening at a first end thereof for removing debris through suction, a hose attachment portion for attaching the suction tip assembly to a suction source, and an ejection wire channel. The apparatus further includes an ejection wire assembly having an ejection wire extending within the channel and an ejection button integral with or connected to the ejection wire. Applying a force to the ejection button advances the ejection wire through the channel such that an end portion of the ejection wire enters the suction tip and dislodges debris clogging the suction tip. The ejection wire may include an enlarged end portion such as, for example a ball tip. One or more of the components of the apparatus may be single-use and disposable.

An anti-clog suction tip apparatus includes a suction tip having a suction opening and an interior defining a suction channel. An ejection wire channel extends to a wire exit opening into the suction channel that is located proximate the suction opening. An ejection wire including a ball tip at an end thereof occupies the ejection wire channel and is transitionable between a retracted configuration and an advanced configuration such that, in the retracted configuration, the ejection wire including the ball tip is retained within the ejection wire channel and does not obstruct suctioning of debris through the suction channel; and in the advanced configuration, the ball tip of the ejection wire does not extend more than three millimeters beyond the suction opening.

Disclosed is a chest drainage system which reduces or eliminates pooling of blood/liquid and/or clogging/clotting in the drainage tube. Generally, the chest drainage system continuously monitors chest tube status and clears pooled liquid when necessary to restore negative pressure to the chest. The system may include a valve device which is located between the patient's chest tube and drainage tube and may be used with any standard chest tube. The chest drainage system also includes a controller for monitoring the pressure at or near the valve device and/or at or near the suction device, and possibly a pump for assisting in clearance of pooled liquid and/or clots. The controller may also control the valve device and/or suction device in response to pressure signals.