An integrated ocular fluid management system that, in one instance, includes a first chamber connected to a first input line and a first output line. A second chamber is connected to a second input line and a second output line. A first pump communicates with the first output line. A second pump communicates with the second input line. A first pressure regulator communicates with the first chamber. A second pressure regulator communicates with the second chamber. A first diaphragm is in the first chamber; and a second diaphragm is in the second chamber. A first controller controls at least one of the first pump and the first pressure regulator to maintain the first diaphragm in a predetermined position. A second controller controls operation of at least one of the second pump and the second pressure to maintain the second diaphragm in a predetermined position.

Disclosed herein are devices, systems, and methods for accurately tracking the amount of flushing liquid delivered to a patient. The disclosed systems monitor the usage of flushing liquid during an operation using a flow sensor or flow probe. The disclosed systems use a flow sensor to measure the flow rate of liquid through a conduit. Using the flow-related data, a processor can calculate the amount of flushing liquid used. This information can be displayed and/or provided to a fluid monitoring system. With this information, together with the total volume of effusion liquid in a collection container, the disclosed systems can accurately determine how much blood is lost from the patient.

A method for operating a fluid management system includes automatically detecting an unstable condition in the system, which may include detecting a large change in the supply fluid amount (indicative of a bag change), detecting a large change in the waste fluid amount (indicative of a bag change), or detecting a large difference between the amount of fluid dispensed as measured by the weight data and the amount of fluid dispensed as measured by the flow data (indicative of a blockage in the supply tubing). The method further includes adjusting the operating mode of the system during the unstable condition, which may include switching to using flow data rather than weight data to track the fluid deficit during a supply bag exchange, halting operation of an outflow pump during a waste container exchange, and/or halting operation of the system during a blockage in the supply tubing.

Procedures to achieve full subtotal, subcutaneous and suprafascial exeresis of fatty tissue between the skin and the musculature in lipedema and secondary lymphedema patients are provided. The procedures improve the patient's lymphological situation, such that no further manual lymphatic drainage or compression garments are required.

A system for measuring the blood loss comprises a measuring device that determines a hemoglobin concentration of fluid within a container utilizing a light source and a light detector. The container receives blood and other fluids from a patient during a medical procedure. Light from the light source is passed through the blood and other fluids in the container and is detected by the light detector. Based upon a magnitude of light detected, a hemoglobin concentration of the fluid in the container can be determined. A volume-measuring device determines the volume of blood and fluid in the container. Knowing the hemoglobin concentration and volume of fluid in the container, the volume of patient blood loss in the container can be determined. The blood loss measuring device in combination with infusion systems maintains a real-blood volume status so that proper infusion of blood, crystalloid and/or colloid solutions occurs.

The invention provides a flushing system (1) configured to flush the pericardial cavity (PC) of a patient, wherein the system comprises: an infusion liquid outlet (4) to connect a first tube(20) having an infusion liquid lumen to guide a flow of infusion liquid from the system to the pericardial cavity, and an effusion liquid inlet (6) to connect to a second tube (21) having an effusion liquid lumen to guide the effusion liquid flow from the pericardial cavity to the system, a flow rate control system to control the flow rate of the infusion liquid flow at the infusion liquid outlet (4) on the basis of multiple sensor signals, wherein the flow rate control system comprises: a control unit (5) to provide a control signal on the basis of the sensor signals, and a pump device (3) to pump infusion liquid to the infusion liquid outlet (4) at an infusion liquid flow rate, wherein the infusion liquid flow rate is adjustable by the control signal of the control unit (5) and wherein the sensor signals registered by the control unit (5) comprise: an infusion liquid signal representative for the infusion liquid flow to the pericardial cavity, an effusion liquid signal representative for the effusion liquid flow rate from the pericardial cavity, a blood volume signal generated by a hematocrit sensor (12) representative for a blood loss flow rate in the effusion liquid from the pericardial cavity, and a pressure control signal representative for the pressure in the pericardial cavity generated by a pressure sensor positioned inside or in connection with the first tube (20), the second tube (21) or the pericardial cavity. The invention also provides a method of monitoring the blood loss volume or flow rate from the pericardium based on multiple sensor signals as well as, a method of treatment of postoperative cardiac patients in order to reduce the risk of cardiac tamponade, reduce post-operative blood loss and reduce the accumulation of blood and clots in the pericardial cavity, wherein the pericardial cavity of the patient is flushed with a flushing system according to the invention.

Systems and methods for cleaning body cavities are presented. Described embodiments include systems for cleaning feces from the lower GI tract. Also provided are systems for steering such a cleaning system, also useful for steering an endoscope or other tool inserted into a body.

Devices, systems, and methods for measuring the blood loss of a subject during a medical procedure. Blood and other fluids are received within a container, and a blood measurement device determines the hemoglobin concentration of the fluid within the container. The blood measurement device can also calculate the estimated blood loss of the subject based upon the determined hemoglobin concentration and the volume of the fluid within the container and the patient's hemoglobin.

A fluid infusion system includes an air pump connected to an accumulator tank to produce pressurized air that is stored in the accumulator tank. The system can include one or more fluid bag chambers wherein each fluid bag chamber includes an inflatable bladder positioned inside the fluid bag chamber to apply pressure on the fluid bag supported inside the chamber. The fluid bag can be connected by a tube set to deliver fluid from the fluid bag to a surgical tool at a surgical site. The fluid can, for example, be irrigation fluid or distention fluid. The system can include a controller connected to the pump to control the pump to produce the pressurized air and an adjustable pressure regulator can be connected between the accumulator tank and the inflatable bladder to control the pressure of air delivered to the inflatable bladder and the pressure that the fluid is delivered to the surgical tool. A pressure sensor can be connected between the adjustable pressure regulator and the inflatable bladder to measure the air pressure delivered to the inflatable bladder and send the air pressure measurements to the controller. The controller can configure the system display to show the air pressure measured by the pressure sensor.

A fluid management system for use with a fluid reservoir includes an inflow pump and an outflow pump. The inflow pump is connectable to a probe for delivering a distention fluid to a body cavity. The outflow pump removes the distention fluid through the same probe, thus establishing a re-circulating volume of distention fluid within the body cavity. The removed fluid is filtered and returned to a fluid reservoir for eventual recycling to the body cavity. A controller adjusts the flow rates of the inflow pump and the outflow pump to maintain a pre-selected fluid pressure or volume within the body cavity.