Abstract: A delivery device and implantable prosthesis for repairing a soft tissue defect such as an abdominal wall hernia. The delivery device includes a support body that is nested between a first and second layer of the prosthesis. The support body includes a zone of weakness to facilitate collapse of the nested delivery device and prosthesis. A handle extends from the support body and may be used to position the prosthesis as well as to cause the support body to move to a reduced configuration for removal of the support body from the prosthesis.

Abstract: An organ perfusion device includes an inlet for connection to the organ, and an outlet for connection to the organ. The device also includes a perfusion circuit including: a reservoir configured to hold a perfusion fluid; a waste receptacle, and a plurality of fluid conduits. The fluid conduits define: a delivery fluid path connecting the reservoir with the inlet; a return fluid path, independent of the delivery fluid path, connecting the reservoir with the outlet; and a waste fluid path connecting the reservoir with the waste receptacle. The device also includes a first flow control device configured to selectively prevent or allow fluid flow from the reservoir to the organ via the delivery fluid path; and a second flow control device configured to selectively prevent or allow fluid flow from the reservoir to the waste receptacle via the waste fluid path.

Abstract: A device for performing a remote ischemic conditioning treatment. The device includes an inflatable cuff and a cartridge which is a source of gas for inflating the cuff. A first valve controls the flow of gas from the cartridge to the cuff so as to maintain a predetermined pressure in the cuff during an ischemic period. A second valve allows gas to escape from the cuff during a reperfusion period of the remote ischemic conditioning treatment. A controller which may be battery-powered is used to control the opening and closing of the valves. The cartridge may contain a gas, or materials which, under certain conditions, react to produce a gas. The chemical reaction may be initiated by an electrical pulse or signal from the controller.

Abstract: A delivery device and implantable prosthesis for repairing a soft tissue defect such as an abdominal wall hernia. The delivery device includes a support body that is nested between a first and second layer of the prosthesis. The support body includes a zone of weakness to facilitate collapse of the nested delivery device and prosthesis. A handle extends from the support body and may be used to position the prosthesis as well as to cause the support body to move to a reduced configuration for removal of the support body from the prosthesis.

Abstract: A delivery device and implantable prosthesis for repairing a soft tissue defect such as an abdominal wall hernia. The delivery device includes a support body that is nested between a first and second layer of the prosthesis. The support body includes a zone of weakness to facilitate collapse of the nested delivery device and prosthesis. A handle extends from the support body and may be used to position the prosthesis as well as to cause the support body to move to a reduced configuration for removal of the support body from the prosthesis.

Abstract: An organ perfusion device includes an inlet for connection to the organ, and an outlet for connection to the organ. The device also includes a perfusion circuit including: a reservoir configured to hold a perfusion fluid; a waste receptacle, and a plurality of fluid conduits. The fluid conduits define: a delivery fluid path connecting the reservoir with the inlet; a return fluid path, independent of the delivery fluid path, connecting the reservoir with the outlet; and a waste fluid path connecting the reservoir with the waste receptacle. The device also includes a first flow control device configured to selectively prevent or allow fluid flow from the reservoir to the organ via the delivery fluid path; and a second flow control device configured to selectively prevent or allow fluid flow from the reservoir to the waste receptacle via the waste fluid path.

Abstract: Described herein are embodiments of a system and a device for performing remote ischemic conditioning that may be configured to treat a subject in accordance with particular usage restrictions and/or a particular treatment protocol. More particularly, in some embodiments a RIC device may include at least two parts, an inflatable cuff to fit around a limb of a subject and a controller that operates the inflatable cuff to inflate and deflate and thus alternate between ischemia and reperfusion of the limb in accordance with a treatment protocol. The inflatable cuff may include a computer-readable storage and that storage may include usage restrictions and/or configuration settings for the controller, to configure the controller to operate the inflatable cuff in accordance with the usage restrictions and to perform a particular treatment protocol when operating the inflatable cuff.

Abstract: An organ perfusion device includes an inlet for connection to the organ, and an outlet for connection to the organ. The device also includes a perfusion circuit including: a reservoir configured to hold a perfusion fluid; a waste receptacle, and a plurality of fluid conduits. The fluid conduits define: a delivery fluid path connecting the reservoir with the inlet; a return fluid path, independent of the delivery fluid path, connecting the reservoir with the outlet; and a waste fluid path connecting the reservoir with the waste receptacle. The device also includes a first flow control device configured to selectively prevent or allow fluid flow from the reservoir to the organ via the delivery fluid path; and a second flow control device configured to selectively prevent or allow fluid flow from the reservoir to the waste receptacle via the waste fluid path.

Abstract: A remote ischemic conditioning system may be integrated with other medical devices or apparatus so that cycles of remote ischemic conditioning may be performed on a patient before, during and/or after performance of another medical procedure. In one embodiment, a remote ischemic conditioning system may be integrated with a surgery table. In another embodiment, a remote ischemic conditioning system may be integrated with an automated external defibrillator, or an automated external defibrillator/monitor. Integration of the remote ischemic conditioning system with the surgical table or the automated external defibrillator allows the remote ischemic conditioning system to be powered by the power source for the table or the automated external defibrillator, and/or to be controlled by a control panel disposed on the table or the automated external defibrillator.

Abstract: In accordance with an example, an apparatus is for any one of a chargeable electrical device and an electrical device each. The chargeable electrical device and/or and the electrical device are each configured to be plugged into, and to receive power from, an electrical grid. The electrical grid is configured to provide electrical energy in accordance with any one of the electrical energy pricing and electricity availability. The apparatus includes (and is not limited to) a combination of the first control unit and the second control unit.

Abstract: A delivery device and implantable prosthesis for repairing a soft tissue defect such as an abdominal wall hernia. The delivery device includes a support body that is nested between a first and second layer of the prosthesis. The support body includes a zone of weakness to facilitate collapse of the nested delivery device and prosthesis. A handle extends from the support body and may be used to position the prosthesis as well as to cause the support body to move to a reduced configuration for removal of the support body from the prosthesis.

Abstract: A device for performing a remote ischemic conditioning treatment. The device includes an inflatable cuff and a cartridge which is a source of gas for inflating the cuff. A first valve controls the flow of gas from the cartridge to the cuff so as to maintain a predetermined pressure in the cuff during an ischemic period. A second valve allows gas to escape from the cuff during a reperfusion period of the remote ischemic conditioning treatment. A controller which may be battery-powered is used to control the opening and closing of the valves. The cartridge may contain a gas, or materials which, under certain conditions, react to produce a gas. The chemical reaction may be initiated by an electrical pulse or signal from the controller.

Abstract: A system for performing remote ischemic conditioning includes an inflatable cuff configured to encircle a limb of a subject and a controller removably attached to the cuff. The controller includes a pump; a manifold in fluid communication with the pump; a connector in fluid communication with the manifold and in removable fluid communication with the inflatable cuff; a pressure sensor; and a control circuit configured to implement a remote ischemic conditioning treatment protocol.

Abstract: A system for performing remote ischemic conditioning includes an inflatable cuff configured to encircle a limb of a subject and a controller removably attached to the cuff. The controller includes a pump; a manifold in fluid communication with the pump; a connector in fluid communication with the manifold and in removable fluid communication with the inflatable cuff; a pressure sensor; and a control circuit configured to implement a remote ischemic conditioning treatment protocol.

Abstract: A system for performing remote ischemic conditioning includes an inflatable cuff configured to encircle a limb of a subject and a controller removably attached to the cuff. The controller includes a pump; a manifold in fluid communication with the pump; a connector in fluid communication with the manifold and in removable fluid communication with the inflatable cuff; a pressure sensor; and a control circuit configured to implement a remote ischemic conditioning treatment protocol.

Abstract: A system for performing remote ischemic conditioning includes an inflatable cuff configured to encircle a limb of a subject and a controller removably attached to the cuff. The controller includes a pump; a manifold in fluid communication with the pump; a connector in fluid communication with the manifold and in removable fluid communication with the inflatable cuff; a pressure sensor; and a control circuit configured to implement a remote ischemic conditioning treatment protocol.

Abstract: A system for performing remote ischemic conditioning includes an inflatable cuff configured to encircle a limb of a subject and a controller removably attached to the cuff. The controller includes a pump; a manifold in fluid communication with the pump; a connector in fluid communication with the manifold and in removable fluid communication with the inflatable cuff; a pressure sensor; and a control circuit configured to implement a remote ischemic conditioning treatment protocol.