Abstract: Certain aspects relate to articulating medical instruments and corresponding systems and techniques. An articulating medical instrument can include an elongated shaft having two shaft sections and a bending section positioned therebetween. The instrument can include an articulation handle positioned at a proximal end of the shaft, and one or motors positioned within the articulation handle and configured to articulate the first bending section. The instrument can also include an insertion handle coupled to the shaft that enables translation of the shaft relative to the insertion handle.

Abstract: Certain aspects relate to systems and techniques for medical robotic systems that leverage a versatile, open kinematic chain together with a set of medical-procedure-specific software-controlled actuation constraints in order to perform a variety of medical procedures. The robotic system can be operated in a first mode by identifying a remote center and constraining the actuation of motorized joints to maintain intersection of at least an insertion axis with the remote center. The robotic system can be operated in a second mode by identifying a virtual rail position and constraining the actuation of motorized joints to maintain alignment of the insertion axis along the virtual rail.

Abstract: Certain aspects relate to medical instruments including wrists with hybrid redirect surfaces. Such medical instruments can include, for example, a shaft with a wrist positioned at a distal end. The wrist can include a proximal clevis connected to the shaft and a distal clevis pivotally connected to the proximal clevis. The wrist can also include a static redirect surface, such as a face of a clevis, and a dynamic redirect surface, such as a pulley. The instrument can include an end effector connected to the distal clevis. A plurality of pull wires can extend through the shaft and the wrist and engage with and actuate the wrist and the end effector. A first pull wire segment of the plurality of pull wires can engage the static redirect surface, and a second pull wire segment of the plurality of pull wires can engage the dynamic redirect surface.

Abstract: Certain aspects relate to systems and techniques for medical robotic systems that leverage a versatile, open kinematic chain together with a set of medical-procedure-specific software-controlled actuation constraints in order to perform a variety of medical procedures. The robotic system can be operated in a first mode by identifying a remote center and constraining the actuation of motorized joints to maintain intersection of at least an insertion axis with the remote center. The robotic system can be operated in a second mode by identifying a virtual rail position and constraining the actuation of motorized joints to maintain alignment of the insertion axis along the virtual rail.

Abstract: The systems, devices, and methods of the present application relate to robotically-actuated liver retractors. A robotic medical system can include a first robotic arm, and a medical instrument comprising an instrument handle configured to attach to a distal end of a the robotic arm, a rigid proximal portion that extends from the instrument handle, and a distal portion configured to support a liver during a robotic medical procedure.

Abstract: A medical instrument can include alignment and attachment mechanisms for aligning and attaching the medical instrument to another device, such as an adapter on an instrument drive mechanism. For example, a medical system can include a medical instrument having an instrument handle and an elongated body. The system can include an alignment mechanism configured to provide rotational alignment between the medical instrument and an adapter. The system can also include an attachment mechanism configured to secure the medical instrument to the adapter. The attachment mechanism can include at least three locking elements positioned circumferentially about the axis.

Abstract: Systems, devices and methods are provided in which an instrument can translate along an insertion axis. Rather than relying primarily on a robotic arm for instrument insertion, the instruments described herein have novel instrument based insertion architectures that allow portions of the instruments themselves to translate along an insertion axis. For example, an instrument can comprise a shaft, an end effector on a distal end of the shaft, and a handle coupled to the shaft. The architecture of the instrument allows the shaft to translate relative to the handle along an axis of insertion. The translation of the shaft does not interfere with other functions of the instrument, such as end effector actuation.

Abstract: Certain aspects relate to systems and techniques for an articulating monopolar medical instrument. In one aspect, the medical instrument includes a wrist comprising a proximal clevis and a distal clevis; an end effector coupled to the distal clevis via a distal axle; at least one proximal pulley in the proximal clevis; at least one distal pulley in the distal clevis and coupled to the distal axle; a first cable configured to engage with the at least one proximal pulley and the at least one distal pulley; and a second cable configured to engage with the at least one proximal pulley without engaging the at least one distal pulley.

Abstract: Certain aspects relate to medical instruments including wrists with hybrid redirect surfaces. Such medical instruments can include, for example, a shaft with a wrist positioned at a distal end. The wrist can include a proximal clevis connected to the shaft and a distal clevis pivotally connected to the proximal clevis. The wrist can also include a static redirect surface, such as a face of a clevis, and a dynamic redirect surface, such as a pulley. The instrument can include an end effector connected to the distal clevis. A plurality of pull wires can extend through the shaft and the wrist and engage with and actuate the wrist and the end effector. A first pull wire segment of the plurality of pull wires can engage the static redirect surface, and a second pull wire segment of the plurality of pull wires can engage the dynamic redirect surface.

Abstract: Certain aspects relate to medical instruments including wrists with hybrid redirect surfaces. Such medical instruments can include, for example, a shaft with a wrist positioned at a distal end. The wrist can include a proximal clevis connected to the shaft and a distal clevis pivotally connected to the proximal clevis. The wrist can also include a static redirect surface, such as a face of a clevis, and a dynamic redirect surface, such as a pulley. The instrument can include an end effector connected to the distal clevis. A plurality of pull wires can extend through the shaft and the wrist and engage with and actuate the wrist and the end effector. A first pull wire segment of the plurality of pull wires can engage the static redirect surface, and a second pull wire segment of the plurality of pull wires can engage the dynamic redirect surface.

Abstract: A robotic system can include a high force instrument that amplifies input forces such that output forces are greater than input forces. The high force instrument can include an end effector. The high force instrument can further include a first pulley configured to rotate about a pulley axis and a first jaw member connected to the first pulley by a first drive pin. The high force instrument can also include a second pulley configured to rotate about the pulley axis and a second jaw member connected to the second pulley by a second drive pink. A link can provide a first pivot point about which the first jaw member can pivot and a second pivot point about which the second jaw member can pivot.

Abstract: Certain aspects relate to systems and techniques for an articulating monopolar medical instrument. In one aspect, the medical instrument includes a wrist comprising a proximal clevis and a distal clevis; an end effector coupled to the distal clevis via a distal axle; at least one proximal pulley in the proximal clevis; at least one distal pulley in the distal clevis and coupled to the distal axle; a first cable configured to engage with the at least one proximal pulley and the at least one distal pulley; and a second cable configured to engage with the at least one proximal pulley without engaging the at least one distal pulley.

Abstract: A medical instrument can include alignment and attachment mechanisms for aligning and attaching the medical instrument to another device, such as an adapter on an instrument drive mechanism. For example, a medical system can include a medical instrument having an instrument handle and an elongated body. The system can include an alignment mechanism configured to provide rotational alignment between the medical instrument and an adapter. The system can also include an attachment mechanism configured to secure the medical instrument to the adapter. The attachment mechanism can include at least three locking elements positioned circumferentially about the axis.

Abstract: Certain aspects relate to systems and techniques for articulating medical instruments. In one aspect, the instrument includes a wrist having at least two degrees of freedom of movement, and an end effector coupled to the wrist. The end effector can include an upper jaw, a lower jaw, and a firing mechanism configured to form staples in tissue. Actuation of the firing mechanism can be decoupled from the movement of the wrist in the at least two degrees of freedom.

Abstract: Certain aspects relate to systems and techniques for aligning inputs on medical instruments. In one aspect, the method includes receiving, at a data reader of the instrument drive mechanism, alignment data from the tool when the tool is positioned within a threshold distance of the data reader. The tool include one or more inputs and one or more pull wires configured to be actuated by output shafts of the instrument drive mechanism via the one or more inputs. The method also includes receiving, at a processor, the alignment data from the data reader, and rotating, via the processor, the one or more output shafts of the instrument drive mechanism into alignment with the one or more inputs of the tool based on the alignment data. Each of the output shafts is configured to mechanically couple with a corresponding one of the inputs of the tool.

Abstract: Systems, devices and methods are provided in which an instrument can translate along an insertion axis. Rather than relying primarily on a robotic arm for instrument insertion, the instruments described herein have novel instrument based insertion architectures that allow portions of the instruments themselves to translate along an insertion axis. For example, an instrument can comprise a shaft, an end effector on a distal end of the shaft, and a handle coupled to the shaft. The architecture of the instrument allows the shaft to translate relative to the handle along an axis of insertion. The translation of the shaft does not interfere with other functions of the instrument, such as end effector actuation.

Abstract: A robotic system can include a high force instrument that amplifies input forces such that output forces are greater than input forces. The high force instrument can include an end effector. The high force instrument can further include a first pulley configured to rotate about a pulley axis and a first jaw member connected to the first pulley by a first drive pin. The high force instrument can also include a second pulley configured to rotate about the pulley axis and a second jaw member connected to the second pulley by a second drive pink. A link can provide a first pivot point about which the first jaw member can pivot and a second pivot point about which the second jaw member can pivot.

Abstract: Provided are systems and techniques for providing multiple perspectives during medical procedures. In one aspect, a method includes positioning a plurality of cannulas in a plurality of anatomical quadrants of a patient, inserting first and second surgical tools coupled to corresponding robotic arms into the respective cannulas. The method may include inserting an articulatable camera coupled to another robotic arm into another of the cannulas, where the articulatable camera is capable of showing a first view including the first surgical tool in a first anatomical quadrant and articulating to show a second view including the second surgical tool in a second anatomical quadrant. The method may further involve performing a surgical procedure in at least one of the first anatomical quadrant or the second anatomical quadrant.

Abstract: Certain aspects relate to systems and techniques for a bipolar medical instrument. In one aspect, the medical instrument includes a first end effector, a first set of one or more distal pulleys coupled to the first end effector, and a wrist configured to house the first set of distal pulleys. The medical instrument also includes a plurality of cables extending through the wrist and a first insulating member formed between the first end effector and the first set of one or more distal pulleys.

Abstract: Certain aspects relate to systems and apparatuses with shielded wrists, and methods of actuating instruments with wrists. In one aspect, an instrument includes a shaft, an end effector, and a wrist connecting the shaft to the end effector. For example, the wrist may include a proximal clevis, a distal clevis, and an intermediary frame positioned between the proximal clevis and the distal clevis.