Systems and methods for pumping milk from a breast, wherein the milk is expressed from the breast under suction and milk is expulsed from the pumping mechanism to a collection container under positive pressure.

A blood pump is disclosed. The blood pump apparatus is arranged to provide pulsatile flow, and comprises a flexible inner cylindrical duct providing a blood flow region, and an outer cylindrical duct arranged to surround the inner cylindrical duct and arranged to accommodate a pumping fluid. In the pump the inner cylindrical duct is described as comprising a blood inlet for receiving blood into the region, a blood outlet for passing blood out from the blood flow region and a passageway therebetween. There is also described the feature of the inner duct comprising a non return valve at the blood inlet and a non return valve at the blood outlet, the outer cylindrical duct having a fluid port for a pumping fluid, and a pump device arranged to cyclically deliver and withdraw pumping fluid to the fluid port thereby cyclically compressing and expanding the flexible inner cylindrical duct urging blood through the blood flow region and delivering a pulsating blood flow through the blood outlet.

A blood pump is disclosed. The blood pump apparatus is arranged to provide pulsatile flow, and comprises a flexible inner cylindrical duct providing a blood flow region, and an outer cylindrical duct arranged to surround the inner cylindrical duct and arranged to accommodate a pumping fluid. In the pump the inner cylindrical duct is described as comprising a blood inlet for receiving blood into the region, a blood outlet for passing blood out from the blood flow region and a passageway therebetween. There is also described the feature of the inner duct comprising a non return valve at the blood inlet and a non return valve at the blood outlet, the outer cylindrical duct having a fluid port for a pumping fluid, and a pump device arranged to cyclically deliver and withdraw pumping fluid to the fluid port thereby cyclically compressing and expanding the flexible inner cylindrical duct urging blood through the blood flow region and delivering a pulsating blood flow through the blood outlet.

A blood pump is disclosed. The blood pump apparatus is arranged to provide pulsatile flow, and comprises a flexible inner cylindrical duct providing a blood flow region, and an outer cylindrical duct arranged to surround the inner cylindrical duct and arranged to accommodate a pumping fluid. In the pump the inner cylindrical duct is described as comprising a blood inlet for receiving blood into the region, a blood outlet for passing blood out from the blood flow region and a passageway therebetween. There is also described the feature of the inner duct comprising a non return valve at the blood inlet and a non return valve at the blood outlet, the outer cylindrical duct having a fluid port for a pumping fluid, and a pump device arranged to cyclically deliver and withdraw pumping fluid to the fluid port thereby cyclically compressing and expanding the flexible inner cylindrical duct urging blood through the blood flow region and delivering a pulsating blood flow through the blood outlet.

A biological component treatment cassette (blood component collection cassette (28)) is configured to be attachable to a separation device (centrifugal separation device (14)), and a flow path (42) is formed in an interior portion thereof. The biological component treatment cassette includes a wall portion forming a part of the flow path (42, and is equipped with pump action members (first and second pump action members (58, 66)) formed of a soft material and which are pressed by pumps of the separation device. The pump action members include pump pressed portions (first pump pressed portions (58a), second pump pressed portions (66a)).

An example medical device is disclosed. The example medical device includes a tubular scaffold having an inner surface and an outer surface. The medical device also includes a flexible inner member extending along at least a portion of the inner surface of the scaffold. Further, the medical device includes an activation assembly positioned along a portion of the inner member, the activation assembly including a conductive member having a first end region and a second end region, wherein a portion of the first end region is coupled to an activation element, and wherein the second end region is coupled to a power source. Additionally, the power source is configured to deliver an electrical stimulus to the activation element which shifts the inner member between a first configuration and a second expanded configuration.

A pumping assembly includes a flexible tube extending along a longitudinal axis. The flexible tube defines an internal cavity extending along the longitudinal axis. The internal cavity is configured to contain a fluid disposed therein, wherein the fluid is a liquid and/or a gas. A plurality of ferromagnetic or magnetic particles are disposed within at least a portion of a thickness of the flexible tube. The plurality of ferromagnetic or magnetic particles are also disposed extending along the longitudinal axis. A plurality of electromagnets are placed in series adjacent to one another. The flexible tube is disposed adjacent to the plurality of electromagnets. A controller is configured to selectively magnetize at least one electromagnet from the plurality of electromagnets in a progression along the plurality of electromagnets, thereby compressing the tubing in a progression being a pumping action. A power source is electrically connected to the controller.

The present invention relates to method for implanting a medical device for controlling a flow of fluid in a lumen formed by a tissue wall of a patient's urethra. The method is performed by: cutting the skin of the patient, inserting a dissecting tool and dissecting an area of at least one portion of the tissue wall of the urethra, placing an adjustable constriction device in the dissected area in operative engagement with the urethra, placing an operation device configured to operate the adjustable constriction device to control the flow of urine in the urethra in the patient's body, placing a sensor configured to sense a temperature of the medical device in the patient's body, and placing a control unit in the patient's body configured to control the operation device based on information from the sensor.

The present invention relates to method for implanting a medical device for controlling a flow of fluid in a lumen formed by a tissue wall of a patient's urethra. The method is performed by: cutting the skin of the patient, inserting a dissecting tool and dissecting an area of at least one portion of the tissue wall of the urethra, placing an adjustable constriction device in the dissected area in operative engagement with the urethra, placing an operation device configured to operate the adjustable constriction device to control the flow of urine in the urethra in the patient's body, placing a sensor configured to sense a temperature of the medical device in the patient's body, and placing a control unit in the patient's body configured to control the operation device based on information from the sensor.

A surgical method of treating a patient is disclosed. The method comprises the steps of: cutting the patient's skin and abdominal wall; dissecting an area of the patient's intestine; and dissecting a portion of the dissected intestinal area such that intestinal mesentery connected thereto is opened in such a way that supply of blood through the mesentery to the dissected intestinal area is maintained as much as possible on both sides of the dissected portion. The method further comprises the steps of dividing the patient's intestine in the dissected portion so as to create an upstream part of the intestine with a first intestinal opening and a downstream part of the intestine with a second intestinal opening with the mesentery still maintaining a tissue connection between the upstream and downstream intestine parts.