Abstract: Surgical devices and methods are provided that utilize an end effector biased to a closed position when an actuator of the device is biased in an uncompressed configuration. End effectors according to the present disclosure can include first and second jaws that can be moved from the biased closed position to an open position by compressing the actuator from the uncompressed configuration and towards a compressed configuration. Various force assemblies and related components are provided that allow the device to achieve two end effector actuation profiles: (1) moving from a closed position and to an open position; and (2) moving from a closed position, to an open position, and back to the closed position. Various structures and methods for operating such devices during a surgical procedure are also provided.

Abstract: Methods and devices are provided for retracting a cutting assembly in the event of a failure on a motorized electrosurgical device. As an example, a surgical device is provided that includes a handle portion with an elongate shaft extending distally that has first and second jaws configured to engage tissue therebetween. A cutting assembly cuts tissue engaged between the first and second jaws. A drive shaft extends from the handle through the elongate shaft and moves the cutting assembly. A motorized gear assembly moves the drive shaft. The drive shaft is movable between a first position in which the drive shaft is engaged with the motorized gear assembly such that actuation of the motorized gear assembly drives the drive shaft, and a second position in which the drive shaft is disengaged from the motorized gear assembly such that the drive shaft can move independent of the gear assembly.

Abstract: Surgical devices are provided having power-assisted or fully powered jaw closure. The devices herein generally include a handle portion, an elongate shaft, and an effector having first and second jaws configured to engage tissue. A motor and one or more compression springs can be operatively coupled, and activation of the motor can compress the spring(s) to reduce the amount of user supplied force to compress tissue between the jaws. In some embodiments, the devices can be configured to regulate an amount of compression applied by the jaws prior to, during, and/or after cutting of the tissue to promote hemostasis. For example, the devices can include sensors, processors, and/or other components that analyze data indicative of tissue type and tissue load. Based on this feedback, the device can automatically adjust the amount of compression or energy applied to the tissue to seal the tissue.

Abstract: Surgical devices and methods are described herein that provide energy density control during tissue sealing. In general, these devices include a handle portion, an elongate shaft, and an end effector having a first jaw having a first tissue engaging surface and a second jaw having a second tissue engaging surface. The first tissue engaging surface can include an energy delivering electrode having a selected pattern of varying conductivity which may include a discrete region or a continuous pattern. The energy delivering electrode may be formed from a polymer substrate that includes a metal. The metal may be mixed into the substrate using an ion beam process. The amount of ions in the ion beam, the energy of the ion beam, or both may be varied to create the selected pattern of varying conductivity.

Abstract: A surgical instrument including a handle assembly and an end effector, including a first jaw pivotably coupled to a second jaw, is disclosed. The handle assembly may comprise a jaw position sensor comprising a switch, a closure trigger, and a clamp spring actuatable by the closure trigger. The closure trigger may be configured to: rotate between a first position and a second position, wherein the first position corresponds to the first and second jaws in an open position and the second position corresponds to the first and second jaws in a closed position, and activate the switch of the jaw position sensor at a predetermined rotated position. The clamp spring may be configured to: cause the first and second jaws to transition between the open position and the closed position, and apply a force to the first and second jaws.

Abstract: A surgical system includes a detector that includes an array of pixels configured to detect light reflected by a surgical device and generate a first signal. The first signal includes a first dataset representative of a visible image of the surgical device. The surgical system also includes a processor configured to receive the first signal and a second signal representative of one or more operating parameters of the surgical device. The processor is also configured to generate a modified image of the surgical device that includes information related to one or more operating parameters.

Abstract: A surgical system includes a first detector that includes a first array of pixels configured to detect light reflected by a surgical instrument and generate a first signal comprising a first dataset representative of a visible image of the surgical instrument. The surgical system also includes a second detector, comprising a second array of pixels configured to detect infrared radiation produced by the surgical instrument during a procedure using the surgical instrument and generate a second signal comprising a second dataset representative of an infrared image of the surgical instrument. The surgical system further includes a processor configured to receive the first and second signals, identify from the first dataset data representative of the surgical instrument, and identify from the second dataset data representative of one or more regions of the surgical instrument above a predetermined threshold temperature.

Abstract: Surgical tools are provided herein that have a housing and an elongate tool shaft extending from the housing with an end effector on a distal end thereof. The end effectors deliver electrical energy onto and/or through tissue, and the end effectors are configured to display at least one location of one or more paths of the electrical energy through the end effector.

Abstract: A dual one-way check valve arrangement that may be used for assessing an operating condition of at least one of first and second check valves situated in series along/within a section of a patient-specific section of tubing. A pressure sensor may be associated with at least part of the flow path between the first and second check valves and may be operable to provide an indication of a failed condition of at least one of the first and second check valves. In one embodiment, the pressure sensor may change from a first state to a second state upon fluid pressure within the flow path between the first and second check valves falling below a predetermined level. For instance, the predetermined level may be a cracking pressure of at least one of the first and second check valves. The change in state may be visually discernible on an exterior of the pressure sensor.

Abstract: Surgical instruments and methods for controlling temperature are described herein and can have particular utility when sealing tissue. In one embodiment, an end effector can include first and second jaw members configured to clamp tissue therebetween, and an electrode having a single continuous conductive surface that is coupled to the first jaw member. The end effector can also include a plurality of electrical insulators of varying thermal conductivity disposed between the electrode and the first jaw member coupled thereto. The electrode can be divided into a plurality of thermal zones by at least one opening formed therein and the plurality of electrical insulators can be arranged such that at least a first thermal zone contacts an electrical insulator having a first thermal conductivity and at least a second thermal zone contacts an electrical insulator having a second thermal conductivity that is higher than the first thermal conductivity.

Abstract: An end effector of an electrosurgical device may include a discharge port in communication with a first fluid path, an aspiration port in communication with a second fluid path, a first and second electrode, and a diverter in mechanical communication with the two electrodes. The diverter may receive, on its surface, a fluid emitted by the discharge port, and maintain a contact of the fluid with the first and second electrodes. The diverter may be further configured to prevent an aspiration, by the aspiration port, of the fluid on its surface. An electrosurgical device may include a source port in communication with a first fluid path, an evacuation port in communication with a second fluid path, a first and second electrode, and a housing. The device may include a shaft extending distally from the housing and the end effector as described above.

Abstract: A surgical instrument includes a temperature sensor and a control unit that is operable to deactivate an end effector of the surgical instrument. In some versions the temperature sensor detects the temperature of a transducer, while in others the temperature sensor detects the temperature of the end effector. The surgical instrument may also include a trigger and a trigger position sensor. A force sensor or a position sensor may be included to determine the force and/or position of the transmission assembly. The end effector may also include a force sensor or a micro coil. A surgical instrument having a sensor may be included in a surgical system that includes a control unit and a remote controller. In some instances the remote controller may have one or more force-feedback components. In addition, a device interface and a surgeon interface may be included to remotely adjust the settings of the control unit.

Abstract: A robotic surgical system is provided that includes an electromechanical tool coupled to a surgical instrument such as an end effector of the tool is adapted to apply ultrasound and/or radiofrequency (RF) energy to tissue when the end effector is in contact with the tissue. The end effector is configured to measure force exerted by the tissue on the end effector, which corresponds to tension at the tissue engaged by the end effector. A controller operatively coupled to the tool and the arm is configured to adjust a power applied to the tissue based on the measured force on the end effector. The controller can also adjust a type of energy such that one or both ultrasound and RF energy is selected to be applied to the tissue, based on measured force exerted by the tissue on the end effector.

Abstract: A robotic surgical system including a control system that controls the movement of a robotic arm is described. The robotic arm can be coupled to a tool assembly that includes an end effector positioned at a distal end of a shaft. The control system can assist with controlling the movement of the end effector and any tooling (e.g., cutting tool, boring tool, jaws, etc.) associated with the end effector, such as for either cutting through tissue or controlling a tension in the tissue. The tool assembly can include one or more sensors that measure a variety of forces or velocities associated with either the robotic arm or end effector. The control system can collect and monitor such sensed forces and velocities to determine and control one or more appropriate movement parameters associated with the robotic arm thereby controlling the cutting of tissue and preventing unwanted cutting of tissue. Furthermore, movement parameters associated with more than one robotic arm can be controlled by the control system.

Abstract: A surgical instrument including a shaft including a distal portion and an articulatable portion is disclosed. The articulatable portion, positioned proximal to the distal portion, includes a plurality of joint members. A first articulation cable extends through each first channel of each of the plurality of joint members and a second articulation cable extends through each second channel of each of the plurality of joint members to the distal portion. The first and second articulation cables are transitionable between: (i) an unlocked state, where the first and second articulation cables are free to translate distally and proximally and the plurality of joint members are slidable relative to one another to pivot the distal portion away from a longitudinal axis, and (ii) a locked state, where translation of the first and second articulation cables is locked, causing a position of the distal portion relative to the longitudinal axis to be locked.

Abstract: A robotic surgical system including a control system that controls the movement of a robotic arm is described. The robotic arm can be coupled to a tool assembly that includes an end effector positioned at a distal end of a shaft. The control system can assist with controlling the movement of the end effector and any tooling (e.g., cutting tool, boring tool, jaws, etc.) associated with the end effector, such as for either cutting through tissue or controlling a tension in the tissue. The tool assembly can include one or more sensors that measure a variety of forces or velocities associated with either the robotic arm or end effector. The control system can collect and monitor such sensed forces and velocities to determine and control one or more appropriate movement parameters associated with the robotic arm thereby controlling the cutting of tissue and preventing unwanted cutting of tissue. Furthermore, movement parameters associated with more than one robotic arm can be controlled by the control system.

Abstract: An electrosurgical device is disclosed. The electrosurgical device includes a handle, a shaft extending distally from the handle, and an end effector coupled to a distal end of the shaft. The end effector comprises a first electrode and a second electrode. The second electrode includes a first position and a second position. The second electrode is configured to move from the first position to the second position when a force is applied to the end effector by a tissue section. The first electrode and the second electrode define a treatment area when the second electrode is in the second position.

Abstract: Various embodiments are directed to methods for use with a surgical device to harvest energy from a surgical generator. The surgical device in use in conjunction with the surgical generator may comprise an energy storage device in electrical communication with a surgical generator to provide energy to charge the energy storage device. The method may comprise the steps of receiving a drive signal from the generator. The method may also comprise directing at least a portion of the drive signal to the energy storage device in a first mode. The method may further comprise directing at least a portion of the drive signal to at least one energy element in a second mode.

Abstract: An electrosurgical device includes a body, an end effector, a cutting member, and a shaft. The end effector comprises a pair of jaws and at least one electrode that is operable to deliver RF energy to tissue clamped between the jaws. The cutting member is operable to cut tissue clamped between the jaws. The shaft includes an articulation section that is operable to selectively position the end effector at non-parallel positions relative to the longitudinal axis of the shaft. The body includes a controller operable to selectively actuate the articulation section. The controller may include a rotary knob, a pivoting knob, or a pivoting fin, among other things. An electrical coupling may contact a conductive moving member along at least two axes. A resiliently biased lever may assist a trigger in returning from an actuated position to a home position.

Abstract: An end effector for operating on tissue comprises an upper jaw, a lower jaw, a flexible member, and a pair of conductive members. The upper jaw and the lower jaw are configured to receive tissue when in an open position and the upper jaw is movable toward the lower jaw. The flexible member is coupled to either the upper jaw or the lower jaw, and is configured to deform in response to compression of tissue between the jaws. One of the conductive members is associated with the flexible member and is configured to move with the flexible member in response to compression of tissue between the jaws. The end effector may be configured to manipulate the position of muscle within tissue in response to compression of tissue between the jaws.