The medical device guidance system include a magnetic guidance device which generates a guidance field in an arbitrary direction to guide a capsular medical device and carry out movement and posture control, a position detection device which detects the present position by a magnetic field generated by the capsular medical device and a position calculating and correcting section which forms an estimation equation of an undesired magnetic field generated from a guidance coil and subtracts an estimation equation result from the detection result of the magnetic field detecting section, according to the present position of the capsular medical device that controls the position and posture by a guidance field relative to the position detection device, and corrects the present position by excluding a desired magnetic field generated from a guidance coil.

A magnetic field generator that comprises at least three groups of magnets, the magnetic moment of each magnet being rotatable about a rotation axis, wherein each group comprises at least two magnets, and each group has an orientation in the sense that the rotation axes of the magnetic moments of the magnets of the same group extend in the group's orientation. The orientations of the different groups are linearly independent.

A system and method for manipulating devices, such as a medical implant arranged within a subject, is provided. For non-invasive manipulation of a medical implant, a subject having a non-ferromagnetic medical implant arranged therein is arranged within a system having a static magnetic field and a plurality of adjustable magnetic fields. The non-ferromagnetic medical implant includes at least one cavity and at least one ferromagnetic or ferrimagnetic material arranged within the at least one cavity. The plurality of adjustable magnetic fields of the system are controlled to induce forces on the at least one ferromagnetic or ferrimagnetic material arranged within the at least one cavity to thereby apply the induced forces to the non-ferromagnetic medical implant to effectuate a non-invasive, in vivo manipulation of the non-ferromagnetic medical implant. Other implementations include the manipulation devices such as robotic medical systems, using magnetic fields to drive the robotic medical system.

A drive system for achieving supra-aortic access and neurovascular treatment site access includes a guidewire hub configured to adjust an axial position and a rotational position of a guidewire, a procedure catheter hub configured to adjust an axial position and a rotational position of a procedure catheter, a guide catheter hub configured to adjust an axial position of a guide catheter, and an access catheter hub configured to adjust an axial position and a rotational position of an access catheter, the access catheter further configured to laterally deflect a distal deflection zone of the access catheter.

A magnetic drive system is disclosed. The magnetic drive system comprises: a first magnetic field generation unit; a second magnetic field generation unit which is disposed under the first magnetic field generation unit in a Z-axis direction with an operation area interposed therebetween, and generates a magnetic field in the operation area in combination with the first magnetic field generation unit; and a moving module for moving at least one of the first magnetic field generation unit and the second magnetic field generation unit.

A method for controlling a movement of a medical device in a magnetic field, the medical device having a set of coils includes determining a torque that needs to be applied onto the medical device such that the medical device carries out the movement, determining a minimum current that needs to be supplied to each coil of the set of coils, respectively, to reach the determined torque by solving an optimization problem, and supplying the determined minimum current to each coil of the set of coils, respectively, such that the medical device carries out the movement.

Disclosed herein are lock mechanisms configured for locking and unlocking rotation of a driver and a driven gear system in implantable distraction and compression systems, and implantable medical devices and implantable distraction and compression systems including such lock mechanisms. The lock mechanisms include a keeper that is configured to move from a locked position to an unlocked position in response to a rotation of the driver, wherein, in the locked position, the keeper is configured to resist rotation of the driven features and the driver under a load on the driven features, and in the unlocked position, permits rotation of the drive gear and the driver.