Class / Patent application number | Description | Number of patent applications / Date published |
623300110 | Including electrical or magnetic means adjacent to flexible diaphragm or chamber to effect contraction thereto (e.g., electromagnet, shape memory material, etc.) | 20 |
20090254178 | Heart Booster Pump With Magnetic Drive - A blood flow pump has a housing with an axis. The pump is mounted concentrically about the axis in the housing, defining a chamber. A pusher plate in the housing is concentric with the axis. The pusher plate is substantially non-rotatable relative to the housing and movable in forward directions along the axis. A pair of driven magnets are mounted to the pusher plate and offset from the axis. A pair of driving magnets are mounted to a support member that is driven by a drive shaft. The driving magnets are offset from the drive shaft so that when rotated, their magnetic fields pass through the magnetic fields of the driven magnets. The magnetic field are arranged to oppose each other, creating a repelling force to cause the pusher plate to push the pump element in a pressure stroke direction. | 10-08-2009 |
20090287305 | Wholly implantable non-natural heart for humans - A wholly implantable non-natural heart for humans is a double pump configuration provided with two auricles and two ventricles. Both the said auricles and ventricles are driven by solenoid actuators interacting with high energy magnets; the auricles and ventricles which are hollow chambers are provided with one-way valves in the usual manner, for the purpose of effectively and rhythmically moving blood to and from the said chambers; power generation for driving said solenoid actuators, as well as an electronic control unit is accomplished by a power generating module which could be a simple battery, a miniature spring-driven generator, a mems generator or a redundant self-sustaining generator or a combination of all of the above; the self-sustaining generator has been proposed and designed to power this present artificial heart and will be presented in a separate patent application in the near future as a follow up to this present one; the aforementioned electronic control unit is preferably configured to amplify the signals from the power generating unit as well as utilizing input/output signals from temperature and pressure sensors embedded in the heart to vary contractile force and frequency of beats, based on bodily requirements, thereby mimicking some functions of the natural heart; the electronic unit is also preferably provided with a translator chip that converts signals from the cardiac/vargus trunks (sympathetic and parasympathetic nerves) via electrodes into clear electric currents for varying actuator outputs; the heart would be implanted in the normal position in the chest, atop the diaphragm, while the electronic control unit and the power generation module would preferably be implanted behind the breastbone and lower abdomen respectively; all components of the present invention are amenable to current mass production techniques and miniaturization for the purpose of fitting into individuals of various sizes; as is clearly shown in FIG. | 11-19-2009 |
20100234941 | LINEAR DRIVE AND PUMP SYSTEM, IN PARTICULAR AN ARTIFICIAL HEART - The invention relates to an electrical linear drive, in particular for a pump system of an artificial heart, with a movable part and a stationary part, wherein the stationary part is formed by a permanent magnet arrangement and the movable part is formed by a coil arrangement, or vice versa, and wherein the coil arrangement and the permanent magnet arrangement can be moved to and fro relative to each other in an axial direction by means of current passed through the coil arrangement, wherein the coil arrangement ( | 09-16-2010 |
20110153010 | INTRACARDIAC IMPLANT - TOTAL ARTIFICIAL HEART - The present invention provides methods and systems for a biomaterial medical implant device for treating patients with HF and/or intractable dyrhythmia. It either is implanted inside the cardiac cavity(ies), ICI, or after their removal, TAH. | 06-23-2011 |
20110190880 | Wholly implantable non-natural heart for humans - A wholly implantable non-natural heart for humans includes a pumping unit, a power generating unit, and a controller. An I beam type chassis with matching holes is provided for supporting valve mounting bodies of the non-natural heart. | 08-04-2011 |
20110196485 | HEART HELP DEVICE, SYSTEM, AND METHOD - An implantable device for improving the pump function of the heart of a human patient by applying an external force on the heart muscle is provided. The device comprises at least one heart contacting organ. The heart contacting organ is adapted to be movable to change the position of said force exerted on the heart after the implantable device has been implanted in the human patient. The invention further relates to a method of using said device. | 08-11-2011 |
20110224787 | HEART HELP DEVICE, SYSTEM, AND METHOD - The present invention relates to an implantable device for improving the pump function of the heart of a human patient by applying an external force on the heart muscle, said device comprising at least one pump device comprising: a first part having a first surface, and a second part having a second surface. The first part is displaceable in relation to the second part and said first and second surfaces abut each other, at least partially. The second part exerts, directly or indirectly, force on an external part of said heart muscle. | 09-15-2011 |
20110238172 | BLOOD PUMP - There is provided a blood pump. An exemplary blood pump comprises an impeller with a rotational axis in a pump housing. The exemplary blood pump also comprises a first element that comprises a Lomakin bearing, and a second element physically separated from the first element, the second element comprising a radial magnetic bearing. | 09-29-2011 |
20110313517 | APPARATUS AND METHOD FOR MODIFYING PRESSURE-FLOW CHARACTERISTICS OF A PUMP - A method for modifying a pump of a ventricular assist device includes the step of modifying pressure-flow characteristics of a pump of a ventricular assist device to simulate different pressure-flow characteristics or to make the flow rate of the pump more responsive to changes in the pressure differential of the pump. The step of modifying the pressure-flow characteristics of the pump may includes one or both of the steps of (1) estimating a flow rate of the pump from the speed of an electric motor of the ventricular assist device and from the current or power consumption of the electric motor, wherein the electric motor drives the pump, and (2) adjusting the speed of the electric motor as a function of the estimated flow rate of the pump and a set speed of the electric motor to simulate the different pressure-flow characteristics or to make the flow rate of the pump more responsive to changes in the pressure differential of the pump. | 12-22-2011 |
20120059459 | TREATING CONGESTIVE HEART FAILURE - This document relates to materials and methods for circulatory bypass of a ventricle in the heart of a mammal. For example, materials and methods for bypassing a permanently or temporarily impaired left ventricle in the heart of a mammal (e.g., a human) are provided. | 03-08-2012 |
20120130484 | ARTIFICIAL HEART - Disclosed herein is a fully implantable artificial heart. The use of flat helical springs to align and reciprocate a bellows structure allows the bellows to pump blood, the multiple solenoids with floating magnetized rods and permanent magnet assemblies held by the flat helical springs provide the power. The artificial heart pumps blood with virtually no friction and no parts to wear out. The use of solenoids advantageously move blood in a gentle, controllable manner. | 05-24-2012 |
20120245679 | Device, A Kit And A Method For Heart Support - A device, a kit and a method is presented for permanently augmenting the pump function of the left heart. The mitral valve plane is assisted in a movement along the left ventricular long axis during each heart cycle. The very close relationship between the coronary sinus and the mitral valve is used by various embodiments of a medical device providing this assisted movement. By means of catheter technique an implant is inserted into the coronary sinus, the device is augmenting the up and down movement of the mitral valve and thereby increasing the left ventricular diastolic filling when moving upwards and the piston effect of the closed mitral valve when moving downwards. | 09-27-2012 |
20120245680 | HEART PUMP CONTROLLER - A heart pump including first and second cavities, each cavity including a respective inlet and outlet, a connecting tube extending between the first and second cavities, an impeller including: a first set of vanes mounted on a first rotor in the first cavity portion; a second set of vanes mounted on a second rotor in the second cavity portion; and, a shaft connecting the first and second rotors, the shaft extending through the connecting tube, a drive for rotating the impeller and a magnetic bearing including at least one bearing coil for controlling an axial position of the impeller, at least one of the drive and magnetic bearing being mounted outwardly of the connecting tube, at least partially between the first and second cavity portions. | 09-27-2012 |
20120323318 | FLEXIBLE MAGNETIC MEMBRANE BASED ACTUATION SYSTEM AND DEVICES INVOLVING THE SAME - A flexible magnetic membrane based actuation system comprising magnetic nanoparticles loaded into a polymeric material such as polyurethane and adapted to actuation of to and fro pumping motions of the membrane under application of magnetic field on the magnetic nanoparticles loaded membrane. More particularly, the present invention is directed to the said nanoparticles-loaded polyurethane magnetic membrane based actuation system adapted to function as displacement membrane for various activities requiring such to and fro motion. The magnetic membrane actuation is adapted to be controlled using electronic equipments to regulate the rate, force and frequency of displacement pulses. The magnetic membrane is thus capable of providing a simple, bio-compatible and cost effective means for displacement/mechanical work to assist functioning of various gadgets/medical devices including function as an artificial support system for heart, non-responsive diaphragm or a non-responsive sphincter, and thus capable of wide industrial applications. | 12-20-2012 |
20130178932 | BI-VENTRICULAR PERCUTANEOUS CABLE - A percutaneous cable includes a cable body having a first end and second end, the cable body including a sheath adapted to traverse a patient's skin. The cable includes a plurality of conductors disposed within the cable body configured to transmit power and control data between a system controller and two implantable pumps. The cable includes a first connector disposed at the first end of the cable body and coupled to the plurality of conductors, the first connector configured to connect the cable body to the system controller. The cable includes a second connector disposed at the second end of the cable body, the second connector comprising a first set of contacts and a second set of contacts. | 07-11-2013 |
20130231738 | ARTIFICIAL HEART - Disclosed herein is a fully implantable artificial heart. The use of flat helical springs to align and reciprocate a bellows structure allows the bellows to pump blood, the multiple solenoids with floating magnetized rods and permanent magnet assemblies held by the flat helical springs provide the power. The artificial heart pumps blood with virtually no friction and no parts to wear out. The use of solenoids advantageously move blood in a gentle, controllable manner. | 09-05-2013 |
20130331934 | ARTIFICIAL HEART SYSTEM - An artificial heart with a centrifugal pump is disclosed. In one embodiment, the artificial heart includes an impeller disposed in a housing. The impeller is configured to rotate to circulate blood through the housing. The impeller may include a set of blades on a first side of the impeller and a set of vanes on a second side opposite the first. The blades on the first side and the vanes on the second side allow blood circulation from both the first and the second sides of the impeller. The artificial heart may also or instead include a diffuser with adjustable vanes that enable variation in the output characteristics of the artificial heart pump. Various other artificial hearts, pumps, systems, and methods, including control systems and methods, are also disclosed. | 12-12-2013 |
20140194984 | System and Method for Assisted Partitioning of Body Conduits - A treatment strategy for treatment of elevated pressure in a body conduit, such as a pulmonary vein, with a prosthetic partitioning device for placement in and/or about pulmonary veins is described, as well as delivery systems, and strategies for use thereof. A control device is configured to transmit signals to the prosthetic device to effectuate the repetitive transition between a first, less restricted flow configuration and a second, restricted flow configuration are described. A sensor device may be provided for monitoring physiological parameters of the patient, and can provide signals to the control device for effectuating the transition between the first and second configuration. | 07-10-2014 |
20140309733 | Bi-Ventricular Percutaneous Cable - A percutaneous cable includes a cable body having a first end and second end, the cable body including a sheath adapted to traverse a patient's skin. The cable includes a plurality of conductors disposed within the cable body configured to transmit power and control data between a system controller and two implantable pumps. The cable includes a first connector disposed at the first end of the cable body and coupled to the plurality of conductors, the first connector configured to connect the cable body to the system controller. The cable includes a second connector disposed at the second end of the cable body, the second connector comprising a first set of contacts and a second set of contacts. | 10-16-2014 |
20160143739 | PROSTHETIC VENTRICULAR HEART SYSTEM - An implantable heart system for the treatment of a heart with impaired function. The implantable heart system includes a prosthetic heart chamber assembly and a cooperative mechanism. The prosthetic heart chamber assembly comprises a first prosthesis, a second prosthesis, and a prosthetic heart chamber interconnecting the first and second prostheses. One of the prostheses is a valve and the other prosthesis is either a valve or a tubular prosthesis. The cooperative mechanism is selected from the group consisting of an adhesive; an anchor; a filler material; a shape memory element; an expandable member; a pumping agent; material attached to, or forming a part of, the wall of the prosthetic heart chamber; and combinations thereof. | 05-26-2016 |