Abstract: Specimen collectors configured for use with robotic medical systems are described herein. A robotic medical system can include a medical instrument that can be inserted into a patient to capture a specimen. A robotic manipulator can be engaged with the medical instrument and configured to operate the medical instrument. A sterile barrier can be used to separate a sterile field containing the medical instrument from a non-sterile field containing the robotic manipulator. A specimen collector can include a receptacle portion in the sterile field and configured to receive the specimen when the distal end of the medical instrument is withdrawn from the patient and a connector coupled to the receptacle portion and configured to attach to the robotic medical system. The robotic system can deposit the specimen in the receptacle portion.

Abstract: Techniques relate to providing image data, indicators, and/or other data associated with a medical instrument with the appropriate orientation to assist a user in performing a procedure. For example, a user interface can present an image representation representing image data from a scope and/or a working channel indicator indicating an angle of rotation of a working channel of the scope. When the scope rolls, a rotation adjustment can be applied to the image representation to rotate the image representation within the user interface. Further, the working channel indicator can rotate within the user interface.

Abstract: A device is provided for preventing buckling of a flexible elongate member during insertion of the flexible elongate member. The device includes a support frame comprising a first end, a second end, and multiple pairs of support members. The support frame is configured to reversibly move from a collapsed configuration to an expanded configuration when the first and second ends are moved away from each other. The device also includes multiple open channels coupled to the multiple pairs of support members of the support frame. The multiple open channels are configured to allow the flexible elongate member to be top loaded into the multiple open channels. Also, the multiple open channels are maintained in an axial alignment as the support frame is moved between the expanded and collapsed configurations.

Abstract: Certain aspects relate to systems and techniques for an endoscopic system to access, visualize, and treat pathologies in various organs via natural orifices and lumens of various organs. In one aspect, the system includes an elongate shaft configured for insertion into a urinary tract of a patient. The elongate shaft can include a proximal section, a distal section, a tip portion, and a plurality of pull wires extending along the elongate shaft and terminating at the tip portion of the elongate shaft. The plurality of pull wires may include a first and second pull wire. The first pull wire may be configured to articulate each of the proximal section and the distal section in a first direction. The second pull wire may be configured to articulate the distal section in a second direction independently of the proximal section, the second direction being transverse to the first direction.

Abstract: A device is provided for preventing buckling of a flexible elongate member during insertion of the flexible elongate member. The device includes a support frame comprising a first end, a second end, and multiple pairs of support members. The support frame is configured to reversibly move from a collapsed configuration to an expanded configuration when the first and second ends are moved away from each other. The device also includes multiple open channels coupled to the multiple pairs of support members of the support frame. The multiple open channels are configured to allow the flexible elongate member to be top loaded into the multiple open channels. Also, the multiple open channels are maintained in an axial alignment as the support frame is moved between the expanded and collapsed configurations.

Abstract: Systems and methods for integrating and/or registering a shape sensing fiber in or to various instruments are described herein. Registration fixtures and registration techniques for matching the coordinate system of a fiber to the coordinate system of an elongate instrument or other device are provided. Various systems and methods for integrating a shape sensing fiber into an elongate instrument or other device are also described herein.

Abstract: Certain aspects relate to systems and techniques for driving axial motion of a shaft of a medical instrument using a drive device. A drive device configured to facilitate axial motion of an elongated shaft of a medical instrument can include a body comprising a channel configured to receive the elongated shaft of the medical instrument, a roller configured to engage with the elongated shaft such that, when rotated, the roller drives axial motion of the elongated shaft received in the channel, a first drive input coupled to the body, wherein the first drive input is operable by a robotic system to rotate the roller, a cover configured to selectively open or close the channel, and a second drive input coupled to the body, wherein the second drive input is operable to actuate the cover.

Abstract: Certain aspects relate to systems and techniques for driving axial motion of a shaft of a medical instrument using a drive device. Axial motion can include insertion and/or retraction of the instrument. For example, a robotic medical system can include a medical instrument comprising an instrument base and a flexible shaft configured for insertion into a patient, and a first robotic arm attachable to the instrument base of the medical instrument. The system also includes a drive device configured to engage the flexible shaft, and a second robotic arm attachable to the drive device. The second robotic arm is configured to operate the drive device to drive axial motion of the flexible shaft, and the first robotic arm is configured to move in coordination with operation of the drive device.

Abstract: Specimen collectors configured for use with robotic medical systems are described herein. A robotic medical system can include a medical instrument that can be inserted into a patient to capture a specimen. A robotic manipulator can be engaged with the medical instrument and configured to operate the medical instrument. A sterile barrier can be used to separate a sterile field containing the medical instrument from a non-sterile field containing the robotic manipulator. A specimen collector can include a receptacle portion in the sterile field and configured to receive the specimen when the distal end of the medical instrument is withdrawn from the patient and a connector coupled to the receptacle portion and configured to attach to the robotic medical system. The robotic system can deposit the specimen in the receptacle portion.

Abstract: Certain aspects relate to systems and techniques for an endoscopic system to access, visualize, and treat pathologies in various organs via natural orifices and lumens of various organs. In one aspect, the system includes an elongate shaft configured for insertion into a urinary tract of a patient. The elongate shaft can include a proximal section, a distal section, a tip portion, and a plurality of pull wires extending along the elongate shaft and terminating at the tip portion of the elongate shaft. The plurality of pull wires may include a first and second pull wire. The first pull wire may be configured to articulate each of the proximal section and the distal section in a first direction. The second pull wire may be configured to articulate the distal section in a second direction independently of the proximal section, the second direction being transverse to the first direction.

Abstract: Certain aspects relate to systems and techniques for driving axial motion of a shaft of a medical instrument using a drive device. Axial motion can include insertion and/or retraction of the instrument. For example, a robotic medical system can include a medical instrument comprising an instrument base and a flexible shaft configured for insertion into a patient, and a first robotic arm attachable to the instrument base of the medical instrument. The system also includes a drive device configured to engage the flexible shaft, and a second robotic arm attachable to the drive device. The second robotic arm is configured to operate the drive device to drive axial motion of the flexible shaft, and the first robotic arm is configured to move in coordination with operation of the drive device.

Abstract: Certain aspects relate to systems and techniques for driving axial motion of a shaft of a medical instrument using a drive device. A drive device configured to facilitate axial motion of an elongated shaft of a medical instrument can include a body comprising a channel configured to receive the elongated shaft of the medical instrument, a roller configured to engage with the elongated shaft such that, when rotated, the roller drives axial motion of the elongated shaft received in the channel, a first drive input coupled to the body, wherein the first drive input is operable by a robotic system to rotate the roller, a cover configured to selectively open or close the channel, and a second drive input coupled to the body, wherein the second drive input is operable to actuate the cover.

Abstract: Certain aspects relate to systems and techniques for driving axial motion of a shaft of a medical instrument using a drive device. A robotic medical system can include a drive device comprising a pair of rollers configured to engage a shaft of a medical instrument and a processor configured to operate the rollers to drive insertion of the shaft at a first rate during a first insertion period when a distal tip of the shaft is positioned within an access sheath inserted into the patient, and operate the rollers to transition to driving insertion of the shaft at a second rate that is slower than the first rate during a second insertion period when the distal tip of the shaft is positioned beyond a distal tip of the access sheath.

Abstract: Systems and methods for integrating and/or registering a shape sensing fiber in or to various instruments are described herein. Registration fixtures and registration techniques for matching the coordinate system of a fiber to the coordinate system of an elongate instrument or other device are provided. Various systems and methods for integrating a shape sensing fiber into an elongate instrument or other device are also described herein.

Abstract: Systems and methods for integrating and/or registering a shape sensing fiber in or to various instruments are described herein. Registration fixtures and registration techniques for matching the coordinate system of a fiber to the coordinate system of an elongate instrument or other device are provided. Various systems and methods for integrating a shape sensing fiber into an elongate instrument or other device are also described herein.

Abstract: A device is provided for preventing buckling of a flexible elongate member during insertion of the flexible elongate member. The device includes a support frame comprising a first end, a second end, and multiple pairs of support members. The support frame is configured to reversibly move from a collapsed configuration to an expanded configuration when the first and second ends are moved away from each other. The device also includes multiple open channels coupled to the multiple pairs of support members of the support frame. The multiple open channels are configured to allow the flexible elongate member to be top loaded into the multiple open channels. Also, the multiple open channels are maintained in an axial alignment as the support frame is moved between the expanded and collapsed configurations.

Abstract: A device is provided for preventing buckling of a flexible elongate member during insertion of the flexible elongate member. The device includes a support frame comprising a first end, a second end, and multiple pairs of support members. The support frame is configured to reversibly move from a collapsed configuration to an expanded configuration when the first and second ends are moved away from each other. The device also includes multiple open channels coupled to the multiple pairs of support members of the support frame. The multiple open channels are configured to allow the flexible elongate member to be top loaded into the multiple open channels. Also, the multiple open channels are maintained in an axial alignment as the support frame is moved between the expanded and collapsed configurations.

Abstract: Systems and methods for integrating and/or registering a shape sensing fiber in or to various instruments are described herein. Registration fixtures and registration techniques for matching the coordinate system of a fiber to the coordinate system of an elongate instrument or other device are provided. Various systems and methods for integrating a shape sensing fiber into an elongate instrument or other device are also described herein.

Abstract: Systems and methods for integrating and/or registering a shape sensing fiber in or to various instruments are described herein. Registration fixtures and registration techniques for matching the coordinate system of a fiber to the coordinate system of an elongate instrument or other device are provided. Various systems and methods for integrating a shape sensing fiber into an elongate instrument or other device are also described herein.

Abstract: A device is provided for preventing buckling of a flexible elongate member during insertion of the flexible elongate member. The device includes a support frame comprising a first end, a second end, and multiple pairs of support members. The support frame is configured to reversibly move from a collapsed configuration to an expanded configuration when the first and second ends are moved away from each other. The device also includes multiple open channels coupled to the multiple pairs of support members of the support frame. The multiple open channels are configured to allow the flexible elongate member to be top loaded into the multiple open channels. Also, the multiple open channels are maintained in an axial alignment as the support frame is moved between the expanded and collapsed configurations.