A microminiature electro-magnetic coil sensor pull ring with a pull wire attached thereto is used in changing the angle of a distal end of a medical catheter. The tubular pull ring has a connection recess with a flat bottom machined into the full wall thickness and located proximal to a coil wrap area. Circuit wires are electrically connected to the two lead ends of the coil within the connection recess, such that neither the circuit wires nor the lead ends stand proud of the full wall thickness. The coil wrap area is also recessed, and can have side walls defining an offset angle for the turns of the coil. In another aspect, a coil is wound around one of the pull wires for the pull ring.

A flow directed device adapted to be guided by a fuid, such as blood, flow within a tubular structure such as a blood vessel is disclosed, said device comprising a proximal end (100), a distal end (101) and an elongated body (102) in between defining a longitudinal axis (103), characterized in that said distal end (101) comprises a ferromagnetic area or structure (300) capable of deflecting the distal end (101) when subjected to an external magnetic field. A system comprising the device, as well as method of use of the device, are also disclosed.

Devices for use with introducers, endoscopes and catheters, where the devices relate to an articulating mechanism that allows a working end of a medical device to be steerable in order to access or visualize targeted sites in the interior of a patient's body.

The present invention is directed to a novel shape-transferring cannula system, which provides access to tortuous and unsupported paths. The shape-transferring cannula system and method enables exploration of hollow body structures, and creates a custom-contoured access port for insertion and removal of, for example, diagnostic, surgical, or interventional instruments to and from a site within the body to which the physician does not have line-of-sight access.

A catheter system utilizing one or more sensors is described. The catheter can be used as part of an embolic coil system, guidewire system, or combined embolic coil/guidewire system where the devices interact with the catheter system. A variable detachment embolic coil system and guidewire system are also described.

A method for determining a shape of a bendable instrument can include placing the bendable instrument in a neutral position; moving a first control element a first amount until slack is removed from the first control element; moving a second control element a second amount until slack is removed from the second control element; sensing a position of the first control element after moving the first control element the first amount, the sensed position of the first control element being defined as a first control element calibration position; sensing a position of the second control element after moving the second control element the second amount, the sensed position of the second control element being defined as a second control element calibration position. The method can further include bending the instrument by moving one or both of the first control element and the second control element from the respective first control element calibration position and the second control element calibration position; and determining a resulting shape of the bendable instrument based on a distance one or both of the first control element and the second control element respectively moved from the first control element calibration position and second control element calibration.

A medical device includes an inner element and an outer element positioned at least in part around the inner element. At least one of the inner element and the outer element comprises compression-stiffening particles. The compression-stiffening particles are transitionable from a first state to a second state in response to application of pressure. The compression-stiffening particles have a higher rigidity in the second state than in the first state. The medical device also includes a pressure source operably coupled to one or both of the inner element and the outer element to apply pressure sufficient to transition the compression-stiffening particles from the first state to the second state.

A vascular access device to passively open a fluid path within a vasculature. The vascular access device may include a catheter and a guidewire. The catheter may have a proximal end, a tip, and a length of tubing therebetween. The guidewire may extend along the length of tubing and may include a bent portion. At least a portion of the length of tubing may substantially conform to the bent portion such that the tip of the catheter avoids an obstruction within the vasculature.

Implants comprising electrically-responsive hydrogel are described. Systems to provide electricity to induce response in hydrogel-containing implants are described. Methods for utilizing said system and methods for utilizing said hydrogel-containing implants are described.

A system comprises an instrument having a bendable portion with first and control elements extending in the bendable portion and a control system operably coupled to an actuator and a sensor. The control system operates to, while the bendable portion is in a neutral position, command the actuator to move the first control element a first amount until slack is removed from the first control element and command the actuator to move the second control element a second amount until slack is removed from the second control element. The control system also receives a first control element calibration position after moving the first control element the first amount and receives a second control element calibration position after moving the second control element the second amount. The control system also commands the actuator to bend the bendable portion from the neutral position and determine a resulting shape of the bendable portion.