A variable stiffness apparatus to be installed in a flexible member includes a first elongated member, a second elongated member arranged along the first elongated member, and an inducing member. The first elongated member includes a high bending stiffness portion, and a low bending stiffness portion. The second elongated member includes a shape-memory member that takes a low-stiffness state when in a first phase and a high-stiffness state when in a second phase. The inducing member causes a region of the shape memory member that is arranged around the low bending stiffness portion to transition in phase between the first phase and the second phase, so as to change the stiffness of the region of the second elongated member.

A variable-stiffness actuator system includes a shape-memory member in which a stiffness increases by being heated and decreases by radiating heat, a heating member configured to generate heat, a channel arranged along the longitudinal axis of the shape-memory member, a transfer section configured to selectively supply and stop first and second heat transmission fluids into the channel, and a controller configured to control the transfer section. The controller causes the transfer section to supply the first heat transmission fluid and then supply the second heat transmission fluid into the channel, and further to stop the supply of the second heat transmission fluid so that retention of the first and second heat transmission fluids simultaneously occurs in the channel.

A carrying platform for moving a device within a conduit, the carrying platform comprising: a body configured to be moveable within the conduit; a number of clampers provided on the body and configured to releasably engage the conduit for immobilizing the carrying platform relative to the conduit; and a device engagement mechanism provided on the body and configured to releasably engage the device.

An endoscopic instrument (312, 820, 824) includes an outer tubing (206) extending from a proximal tubing end to a distal tubing end, a flexible torque component (200) extending through the outer tubing, an articulation assembly (400, 500, 600, 700, 828), and an end effector (450, 550, 650, 750, 824). The articulation assembly (400, 500, 600, 700, 828) is coupled to the distal tubing end and includes a plurality of segments (404, 408, 504, 604, 704) and at least one control member (412, 512, 612, 712) extending from a proximal control end to a distal control end coupled with the plurality of segments. The control member manipulates an orientation of at least one segment of the plurality of segments responsive to receiving a control input at the proximal control end. The end effector (450, 550, 650, 750, 824) is coupled to a distal end of the flexible torque component such that manipulating the orientation (516, 616, 620) of the at least one segment controls an orientation of the end effector (450, 550, 650, 750, 824) relative to the outer tubing (206) and rotation of the flexible torque component (200) controls an angle of rotation of the end effector relative (450, 550, 650, 750, 824) to the outer tubing (206).

A device includes first and second sheets of first and second elastic materials, respectively, and a control wire. The first sheet has a first thickness and a first length and is shaped to have a first cross-section having a first inner periphery and a first outer periphery. The second sheet has a second thickness and a second length and is shaped to have a second cross-section having a second inner periphery and a second outer periphery. One of the first sheet and the second sheet has a spacing disposed in along one of the first length and the second length, respectively. The first outer periphery is less than or equal to the second inner periphery. The second sheet surrounds the first sheet. The control wire has an end constrained to one of the first sheet the first material and the second sheet. The control wire is disposed within the spacing.

The present invention is directed to an articulate minimally invasive surgical endoscope with a flexible wrist having at least one degree of freedom. When used with a surgical robot having a plurality of robot arms, the endoscope can be used with any of the plurality of arms thereby allowing the use a universal arm design. The endoscope in accordance to the present invention is made more intuitive a to a user by attaching a reference frame used for controlling the at least one degree of freedom motion to the flexible wrist for wrist motion associated with the at least one degree of freedom. The endoscope in accordance to the present invention attenuates undesirable motion at its back/proximal end by acquiring the image of the object in association with the at least one degree of freedom based on a reference frame rotating around a point of rotation located proximal to the flexible wrist.

A deflection device of steerable endoscope includes a first base, a second base, elastic reposition members and tendon wires. The second base is located above the first base along the endoscope center axis. The elastic reposition members are inlaid between the first and the second bases. Each elastic reposition member includes a first plate connecting to the first base, a second plate connecting to the second base, and a waveform bar connecting the first and the second plates. The wave-height of the waveform bar is not parallel to the endoscope center axis. The tendon wires are located on the two opposite sides of each elastic reposition member. The tendon wires are parallel to and distant from the endoscope center axis. Bending of the steerable endoscope is precisely controlled, and structure of the deflection device is simplified in the invention.

Devices, systems, and methods for controlling an intravascular imaging device are provided. For example, in one embodiment a method includes communicating a control signal to an actuator of the intravascular imaging device to cause oscillation of an imaging element of the intravascular imaging device, wherein the intravascular imaging device further includes an acoustic marker; receiving imaging data from the imaging element of the intravascular imaging device; identifying the acoustic marker in the imaging data by determining a correlation between the imaging data and a template representative of the acoustic marker; adjusting an aspect of the control signal based on identifying the acoustic marker; and communicating the adjusted control signal to the actuator of the intravascular imaging device.

A variable-stiffness actuator capable of providing different stiffnesses for a flexible member includes a shape-memory member that can transit in phase between a first phase and a second phase and an inducing member that causes phase transition between the first phase and the second phase into the shape-memory member. The shape-memory member is arranged in the flexible member with at least one free end. The shape-memory member takes a flexible state in which it is easily deformable by an external force when it is in the first stare, so as to provide lower stiffness for the flexible member. The shape-memory member takes a rigid state in which it tends to take a memorized shape memorized beforehand against an external force when it is in the second stare, so as to provide higher stiffness for the flexible member.

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.