An electronic system for a surgical instrument is disclosed. The electronic system comprises a main power supply circuit configured to supply electrical power to a microprocessor, a supplementary power supply circuit configured to supply electrical power to a sensor, and an over current/voltage protection circuit coupled between the main power supply circuit and the supplementary power supply circuit. The over current/voltage protection circuit comprises a current limit switch. The current limit switch comprises a current resistor coupled to an amplifier, wherein, when the amplifier detects a surge current above a predetermined threshold, the amplifier activates a circuit breaker to interrupt the surge current, and wherein when the surge current is remedied, the supplementary power supply circuit rejoins the main power supply circuit and is configured to supply power to the sensor.

An electronic system for a surgical instrument is disclosed. The electronic system comprises a main power supply circuit configured to supply electrical power to a primary circuit, a supplementary power supply circuit configured to supply electrical power to a secondary circuit, and a sleep mode monitor coupled between the main power supply circuit and the supplementary power supply circuit. The sleep mode monitor is configured to indicate one or more sleep mode conditions. The electronic system further comprises a device state monitor coupled to the primary circuit, the device state monitor configured to sense a state of various electrical and mechanical subsystems of the surgical instrument.

A surgical probe is configured to be inserted into a body cavity and to emit beams of light to ablate tissue within the body cavity. The probe further includes sensors to detect properties of tissue in the body cavity and a source of suction to remove material produced by ablation of tissue within the body cavity. The sensors could be configured to operate in combination with beams of light emitted by the surgical probe to detect the location, geometry, fluorophore content, or other information about tissue in the body cavity. The surgical probe can additionally include suction port(s) to secure portions of tissue relative to the surgical probe to allow ablation of portions of the secured tissue and to allow detection of properties of portions of the secured tissue that are maintained in contact with the surgical probe by the suction port(s).

In an example, a monopolar electrosurgical electrode includes an electrosurgical substrate including an electrically conductive material extending in an axial direction from a proximal end to a distal end. The electrosurgical substrate includes an electrosurgical blade. The electrosurgical blade includes (i) a first lateral surface, (ii) a second lateral surface opposite the first lateral surface, (iii) a first major surface extending between the first lateral surface and the second lateral surface on a first side of the electrosurgical blade, and (iv) a second major surface extending between the first lateral surface and the second lateral surface on a second side of the electrosurgical blade that is opposite the first side. The monopolar electrosurgical electrode also includes a first electrode sensor embedded between a plurality of electrical insulation layers on the first major surface of the electrosurgical blade.

A system and method for compensation of angular distortions in a system utilizing light emitters and light sensors disposed on non-parallel jaws may include determining a first point at a first side of a region of interest and a second point at a second side of the region of interest, determining a linear curve including the first and second points, and utilizing the linear curve to remove the angular distortion from the region of interest between the first and second points. A system and method for compensation of angular distortions may alternatively include modeling a non-pulsatile illumination pattern according to the intensities of individual emitters, comparing the pattern according to the model against a non-pulsatile illumination pattern detected using the light sensors, and varying the intensities of the individual emitters based on the comparison until angular distortion has been removed.

A treatment support device is provided with an irradiation unit, a fluorescence detection unit, and a change acquisition unit for acquiring a change degree of a fluorescence signal detected within a first time range within a treatment time. The treatment support device is provided with: a determination unit for determining whether or not the progress of the treatment is in a steady state based on the fact that the change degree of the fluorescence signal within the first time range falls within a predetermined range of the change degree; and an operation control unit for performing predetermined operation control when the progress of the treatment is determined to be in the steady state by the determination unit.

Surgical instruments are disclosed that are couplable to or have an end effector or a disposable loading unit with an end effector, and at least one micro-electromechanical system (MEMS) device operatively connected to the surgical instrument for at least one of sensing a condition, measuring a parameter and controlling the condition and/or parameter.

An end effector for use with a surgical stapling instrument is disclosed. The end effector comprises a first jaw, a second jaw movable relative to the first jaw to grasp tissue therebetween, and a staple cartridge. The staple cartridge comprises staples deployable into the tissue. The end effector further comprises a magnetic sensor configured to measure a parameter indicative of an identifying characteristic of the staple cartridge, an impedance sensor configured to measure a parameter indicative of an impedance of the tissue, and a processing unit in communication with the impedance sensor. The processing unit is configured to determine a property of the tissue based on an output of the impedance sensor.

A surgical stapling system including a shaft assembly transmits actuation motions from an actuator and an end effector compresses and staples tissue. The end effector comprises a channel; an anvil having a staple forming surface is moveable relative to the channel between open and closed positions; the anvil having a magnet at a distal end; and a staple cartridge removably positionable within the channel. The staple cartridge comprises a body supported for a confronting relationship with the anvil in its closed position; a plurality of staple drivers located within the cartridge body support a staple; a Hall effect sensor located at the distal end of the body; and a microprocessor in communication with the Hall effect sensor. The Hall effect sensor and the microprocessor receive power when the staple cartridge is positioned within the channel, and the system is operable to identify a staple cartridge.

The present application relates to an optical system (1) comprising a light beam generator (10) configured to generate a light beam (2) and direct it along an optical path (3), an optical element (19, 24) in said optical path (3) and on which said light beam (2) is incident for redirecting said light beam (2), a sensor (4, 5) attached to said optical element (19, 24), the sensor (4, 5) being configured to generate information indicative of a characteristic of said light beam (2) that is incident on said optical element (19, 24), and a controller (6) configured to adjust one or more characteristics of said optical system (1) in dependence on the information generated by said sensor (4, 5).