A surgical device for automated drilling includes a drill comprising a drill bit configured to bore through bone and a detector comprising a tissue detection sensor. The drill and detector are independently actuable for insertion and removal of the drill bit and the tissue detection sensor in a bore generated by the drill bit. A surgical system can include the surgical device and a controller configured to actuate the drill to bore through bone, actuate the drill to retract the drill bit from the bore, actuate the detector to insert the tissue detection sensor into the bore, and determine a tissue characteristic at a distal location of the bore based on a sensed signal from the tissue detection sensor.

An endoluminal punch system including a sheath and dilator. The endoluminal punch may include energy delivery system capable of being transmitted from the proximal end to the distal end of the endoluminal punch to assist with tissue crossing and incisions. The dilator may include selectively deployable cutting mechanism to create incisions in tissue that are larger than their basic external diameter. The system may also be configured to reduce the risk of generating plastic emboli during insertion of the endoluminal punch.

A method for producing a surgical instrument is disclosed. The method comprises obtaining a handle, wherein the handle comprises a distal end comprising a shaft interface surface and a first set of magnetic elements. The method further comprises obtaining a shaft, wherein the shaft comprises a proximal end comprising a handle interface surface, a second set of magnetic elements, and a third set of magnetic elements. The method further comprises attaching the shaft to the handle, wherein the shaft interface surface is configured to engage the shaft at the handle interface surface, wherein an attractive magnetic force is configured to pull the handle towards the shaft when the first set of magnetic elements interact with the second magnetic elements, and wherein a repulsive magnetic force is configured to repel the handle from the shaft when the first set of magnetic elements interacts with the third set of magnetic elements.

Certain aspects relate to systems and techniques for alignment and docking of robotic arm of a robotic system for surgery. In one aspect, the system includes a robotic arm, a drive mechanism attached to the robotic arm, and a cannula. The system may further include a first sensor coupled to either the robotic arm or the drive mechanism configured to direct automatic movement of the robotic arm towards the cannula, and a second sensor, that is different than the first sensor, coupled to either the robotic arm or the drive mechanism configured to direct manual movement of the robotic arm towards the cannula.

The disclosed embodiments relate to systems and methods for a surgical tool or a surgical robotic system. One example system for detecting disengagement of a surgical tool, includes an end effector connected to and driven by cables of a tool driver, sensors configured to detect forces associated with the cables, and one or more processors. The one or more processors identify cable tensions derived from forces detected by the sensors, compare the tension to a threshold tension value, calculate a velocity norm value based on a vector including the velocity value for each of the cables, compare the velocity norm value to a statistic velocity threshold, and identify a disengagement of at least one of the plurality of cables based on the first comparison and the second comparison.

An electrosurgical system comprising an end effector and a control circuit is disclosed. The end effector comprises a first jaw and a second jaw. At least one of the first jaw and the second jaw is movable to transition the end effector from an open configuration to a closed configuration to grasp tissue therebetween. The control circuit is configured to cause an application of two different energy modalities to the tissue simultaneously and separately during a tissue treatment cycle comprising a tissue coagulation stage and a tissue transection stage.

A spinal construct includes a first member having a first thread form and an implant cavity configured for disposal of the spinal implant. A second member is engageable with a spinal implant and includes a second thread form configured for engagement with the first thread form. A gauge is coupled to the second member. The gauge is configured to measure a force between the second member and the spinal implant when the second member is engaged with the first member. The second thread form is timed with the first thread form to position the gauge in a selected orientation relative to the spinal implant. Systems and methods are disclosed.

Aspects of the disclosure relate to an adjustable implant configured to be implanted into a patient that includes an adjustable portion moveable relative to a housing. The adjustable implant may include various smart components for enhancing operation of the implant. Smart components may include a controller for managing operations and a transducer for communicating ultrasound data with an external interface device. Additional smart components may include a load cell within the housing for measuring an imparted load; a sensor for measuring angular position of the adjustable portion; a dual sensor arrangement for measuring imparted forces; a reed switch; a half piezo transducer; and an energy harvester.

An instrument system includes an instrument, a drive system, and a controller operably connected to a first drive mechanism and a second drive mechanism of the drive system. The controller is configured to operate the first drive mechanism and the second drive mechanism drive a flexible tensioning member of the instrument to cause movement of an end effector of the instrument while maintaining a tension applied to the flexible tensioning member of the instrument in a tension range.

Techniques are described for testing whether an end effector, or component thereof, is correctly or incorrectly installed to a manipulation system. A manipulation system can include a manipulator arm configured to receive an end effector having a first moveable jaw, a transducer configured to provide first effort information of the end effector as the end effector moves, and a processor configured to provide a command signal to effect a first test move of the first moveable jaw, and to provide an installation status of the of the end effector using the first effort information of the first test move.