In combined methods for treating a patient using time-varying magnetic field, treatment methods combine various approaches for aesthetic treatment. A magnetic field generating device is placed proximate to a body region of the patient. The magnetic field generating device generates a time-varying magnetic field with a magnetic flux density in a range of 0.5 to 7 Tesla. The time-varying magnetic field is applied to the body region of the patient in order to cause a contraction of a muscle within the body region. A second therapy may be used by applying one or more of optical waves, radio frequency waves, mechanical waves, negative or positive pressure or heat to the body region of the patient.

A device configured to cut hair using laser light includes a handle portion and a shaving portion. The handle portion includes a battery and a laser light source. The laser light source is coupled to and configured to receive power from the battery. The laser light source is also configured to generate laser light having a wavelength selected to target a predetermined chromophore to effectively cut a hair shaft. The shaving portion includes a support and a single fiber optic supported by the support. The fiber optic has a proximal end, a distal end, an outer wall, and a cutting region positioned towards the distal end and extending along a portion of the side wall. The fiber optic is positioned to receive the laser light from the laser light source at the proximal end, conduct the laser light from the proximal end toward the distal end, and emit the light out of the cutting region and toward hair when the cutting region is brought in contact with the hair.

A laser treatment head in which an elongate applicator is shaped to access a bodily cavity. At the distal end of the applicator is a deflector protected by a window. At a proximal end of the applicator is a drive that can axially displace and rotate the applicator in a helical pattern such that laser beam pulses deflected to the mucosa area applied along a helical path to the wall of the cavity. The drive comprises a stationary hollow shaft inside a rotatable sleeve. The shaft has a helical channel in its outer surface and the sleeve has a longitudinal slot through its wall. A pin attached to the proximal end of the applicator extends through the slot and into the channel. When the sleeve is rotated, the slot advances the pin along the channel, moving the attached applicator in the helical pattern.

An articulating instrument including a distal assembly having first and second configurations and intermediate configurations between them. At least one of the first and second configurations is substantially stable such that the distal assembly of the instrument has a tendency to remain in the stable configuration when placed in that configuration by a user of the instrument. Preferably, the distal assembly terminates in a distal tip unit defining at least one distal feature that is useful for manipulating tissue.

A system for automated laser-assisted dermatological treatment is provided, the system comprises a robot arm assembly, comprising a laser head coupled to the robot arm and a controlling unit. The system is configured to remove an undesirable dermatological condition from skin by directing laser energy to a pre-defined skin surface area intended for treatment essentially in an absence of human attendance. A method for real-time controlling an automated laser-assisted removal of undesirable dermatological condition from skin implemented by a system and a computer program product for causing the computer to execute the method are further provided.

A system includes a focus optic configured to converge an electromagnetic radiation (EMR) beam to a focal region located along an optical axis. The system also includes a detector configured to detect a signal radiation emanating from a predetermined location along the optical axis. The system additionally includes a controller configured to adjust a parameter of the EMR beam based in part on the signal radiation detected by the detector. The system also includes a window located a predetermined depth away from the focal region, between the focal region and the focus optic along the optical axis, wherein the window is configured to make contact with a surface of a tissue.

The device comprises: a laser source (7); a treatment hand-piece (13); a light guide (11) configured to convey a laser beam from the laser source to the hand-piece. The hand-piece (13) is configured to vary the inclination of the laser beam (F2) exiting from the hand-piece with respect to a longitudinal axis (A-A) of the hand-piece.

A tool has a handle and an elongate shaft that extends distally from the handle. A distal portion of the shaft is inserted into a subject during a surgical procedure. An optical fiber delivers laser energy to a tip at the distal portion of the shaft. The tip includes a mechanical cutting mechanism including a moving part that absorbs the laser energy, thermally conducts the absorbed energy to tissue that is disposed between the moving part and another part, and moves with respect to the other part in order to cut tissue that is disposed between the parts using a mechanical force that is lower than a mechanical force that would be required to cut the tissue in the absence of the laser energy. Other embodiments are also described.

An object is to provide a laser treatment tool capable of guiding a plurality of fluids, a laser transmission path insertable into such a laser treatment tool, and an external tube for forming the laser transmission path. In an external tube 80 which forms a laser transmission path 70 together with a lengthy hollow waveguide path 90 for guiding treatment laser light 57a and has an inner insertion space 81 for allowing insertion of the hollow waveguide path 90, a plurality of sub passages 84 and cooling water passages 85 are provided outside the hollow waveguide path 90, inserted into the insertion space 81, along a longitudinal direction of the insertion space 81.

A miniature intraoperative probe (30) capable of forward-imaging with optical coherence tomography. The probe includes a housing (130), an actuator (150) supported by the housing, and a single mode (146) fiber supported by the housing and configured to laterally scan light data reflected from a sample.