A handheld electromechanical surgical device includes a handle assembly, an adapter assembly, a reload, and an electrical assembly. The handle assembly includes a connecting portion having an electrical connector supported therein. The adapter assembly includes an adapter housing selectively connectable to the connecting portion of the handle assembly and an outer tube extending distally from the adapter housing. The reload includes a housing selectively connectable to the outer tube of the adapter assembly and a circuit board assembly disposed within the reload housing. The electrical assembly includes a flex cable having an elongate body positionable against an outer surface of the adapter assembly. A proximal end of the flex cable is positionable within a cavity defined in the adapter housing and configured to electrically connect with the electrical connector of the handle assembly. A distal end of the flex cable is coupled to the circuit board assembly of the reload.

A cartridge for a high intensity focused ultrasound (HIFU) device and a piezoelectric linear motor are disclosed. By using the cartridge for a HIFU device according to the present invention, a transducer module is coupled to a piezoelectric linear motor driveable in water and embedded in the cartridge, heat generated when a conventional step motor is driven is fundamentally removed, an additional cooling fan is not needed, ultra-low power consumption and ultra-precise transfer can be realized, and thus an effective procedure can be performed. A skin beauty device may include ultrasound and high frequency units, apply a high frequency to a skin to be treated so as to crack a stratum corneum, and apply ultrasound to the skin to be treated, and thus a medicament drug can easily penetrate the treated skin. In addition, the piezoelectric linear motor in which a piezoelectric actuator and a moving shaft are stably coupled is provided.

A surgical stapling apparatus includes a loading unit having first and second jaw members, a drive beam, and a firing lockout assembly. The drive beam is axially movable within the loading unit during a firing sequence. The firing sequence includes an advancement stroke which moves the first and second jaw members to an approximated position and a retraction stroke which moves the first and second jaw members to an unapproximated position. The firing lockout assembly includes an iterating plate, a capture gear, and a lockout pin. The iterating plate is disposed adjacent to the drive beam and is incrementally movable proximally within the loading unit during the firing sequence. The capture gear is rotatable between first and second positions during the firing sequence and is configured to move the iterating plate. The lockout pin is configured to lock the drive beam after a pre-determined number of firing sequences.

Single use medical devices that incorporate one or more destruct elements configured to deform during an autoclave cycle, rendering the device visually damaged or unusable. The use of such destruct elements prevents reuse (knowingly or unwittingly) of single use devices on patients after off-label autoclaving.

The present disclosure generally relates to surgical instruments having adjustable stiffness, and more particularly, surgical instruments having adjustable stiffness for ophthalmic surgical procedures. In one embodiment, a surgical instrument includes a probe, a slidable support sleeve, and a rotatable knob. A stiffness level of the probe may be adjusted by rotating the knob, thereby causing linear displacement of the support sleeve along a length of the probe. The knob may further include a dial depicting a series of settings representing different eye sizes and corresponding to preset positions of the support sleeve relative to the probe. Thus, a user may select an optimal stiffness of the probe for a particular eye size by rotating the knob to the corresponding setting.

A surgical device including a handle assembly, an elongated portion, an end effector, a drive shaft, and a wick is disclosed. The wick is disposed within an outer sleeve of the elongated portion and is made from a fibrous material. The wick is configured to transfer moisture from a first portion of the wick to a second portion of the wick.

In an energy control device, a processor detects a gradual decrease start time at which the electric characteristic value in relation to electric energy output to an ultrasonic transducer starts a gradual decrease after a gradual increase. The processor calculates a difference value by subtracting the electric characteristic value from a peak value at gradual decrease start time and calculates an integrated value of the difference value from the gradual decrease start time. The processor executes, based on a fact that the integrated value become greater than a predetermined threshold, at least one of causing to stop or reduce the output of the electric energy to the ultrasonic transducer, and notifying that the integrated value become greater than the predetermined threshold.

In some embodiments, the present disclosure relates to a method of securing an implant into a body of a patient. Initially, the implant is placed into the body of the patient. Then, an impactor tool is used to apply a force to the implant. Subsequent to the application of force to the implant, a portion of an impaction pad on an end of the impactor tool is monitored. When the portion is observed to be deformed, the application of force onto the implant is discontinued.

Provided are a medical device control apparatus using a handpiece motion and a control method using the same. The medical device control apparatus using the handpiece motion comprises a handpiece which is connected with a medical device body to perform a procedure; a gesture detector which is provided in the handpiece and detects the motion of the handpiece to recognize the gesture of the handpiece; an alarm unit which alarms that a mode of the medical device body is changed from a first state to a second state or parameter values are controlled according to the gesture of the handpiece; control switch which is provided in the handpiece to change the mode of the medical device body or control the parameter values output by the medical device body; and a connection cable which connects the medical device body and the handpiece.

This disclosure concerns an exhaled breath collection device (1000) comprising a sensor unit (100) configured to measure a biomarker in exhaled breath, a cooling device configured to reduce a temperature of exhaled breath, a mouthpiece (300) configured to direct exhaled breath towards the cooling device, and a temperature control unit. In the exhaled breath collection device of the present disclosure, the temperature control unit is configured to control the cooling device to reach a target temperature which is set appropriately to correspond with the biomarker to be analysed.