Abstract:
The device for treating the vaginal canal or other orifices, both natural or surgically obtained orifices, by means of a laser beam, comprises a retractor (19) for the wall of the vaginal canal or orifice, associated with a system for directing the laser beam towards said wall, and with at least one electrode for applying a RF current.
Abstract:
The device for treating the vaginal canal by means of a laser beam comprises a retractor for the wall of the vaginal canal, associated with a scanning system for scanning the laser beam towards the wall by means of a pyramidal mirror for laser beam reflection.
Abstract:
An applicator (1) for magnetic therapy comprising a housing with an outer wall (21), which defines an application surface (3A) to be applied to a patient, and in which at least one electrically conductive coil (13) is housed for generating a magnetic field. The housing comprises an outer shell (3) forming the outer wall (21) and an inner shell (11) forming a seat (30) for housing the coil (13), wherein the inner shell (11) comprises a bottom wall (25) facing the outer wall (21) formed by the outer shell (3). In the housing, a refrigerating device (16) is provided, comprising at least one refrigerating duct (15) adapted to circulate a refrigerating fluid and arranged between the coil (13) and the application surface (3A), and a gap (33) is formed between the bottom wall (25) of the inner shell (11) and the outer wall (21) of the outer shell (3) for thermally insulating the coil (13) and the application surface (3A) from each other; and spacing elements (35) are arranged in the thermal insulation gap (33) between the outer wall (21) of the outer shell (3) and the bottom wall (25) of the inner shell (11).
Abstract:
The applicator device (15) comprises: - a housing (31) comprising a mounting interface (47) for a laser emitter (49); - associated with the housing (31) and solidly connected thereto, a cooling plate (33) with an epidermal contact surface (33.1); - a heat removal system (35) for removing heat from the cooling plate (33).
Abstract:
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.
Abstract:
The device comprises a laser source (7) adapted to emit a laser radiation at a wave- length between around 620 nm and around 750 nm, and a handpiece (5). The handpiece in turn comprises an applicator (11) with a contact surface with the epidermis defining a window (11.1) for the passage of a laser beam (F) toward the epidermis (E) of a subject to be treated. A waveguide (10) conveys the laser radiation from the laser source (7) to a scanning system (17) of the handpiece.
Abstract:
A method for making laser engravings on a web (10) of paper, comprising the steps of prearranging a paper web (10) conveying means (86) configured for conveying said web in a predetermined direction; defining a working area (12) along a path of said web (10); prearranging an emitter (14) of laser pulses (15,15', 16) that have a power set to form engravings on said web (10); prearranging a movable pointing means, comprising a reflection means (22,23) and of focus means (33), arranged to send of said laser pulses (15,15', 16) to said working area (12); selecting an engraving pattern (20) to be engraved on said web (10) by said laser pulses (15,16) emitted as pulse packets in quick succession, said pattern associated with a first function (31) defined in said working area (12) with respect to a first reference (11) that is integral to said web (10); calculating an instruction file (24) containing pointing instructions for operating said pointing means (22,23,33) in such a way that a predetermined position of said movable pointing means (22,23,33) corresponds to each pulse packet, a predetermined position of said points on said working area (12) corresponding to said predetermined position of the movable pointing means; selecting an emission power (W) of said emitter of laser pulses (14); emitting laser pulses (14) through said emission power (W) by said emitter (14); operating said movable pointing means (22,23,33) according to said instruction file, so that said movable pointing means (22,23,33) sequentially reaches each predetermined position by continuously changing the direction of said laser pulses (15,16) in said working area (12) reproducing said pattern (20) on said web (10); wherein said step of computing an instruction file (24) provides a transform of said first function (31) from said reference system (11) that is integral to said web, (10) into a second reference system (13) that is integral to said emitter (14), wherein a second transformed function (32) is obtained, by said transform, which is defined in said working area (12), and said instructions of said instruction file (24) operate said pointing means (22,23,33) in such a way that said laser pulses (16) describe said transformed function (32) with respect to said second reference system (13), in said working area (12), such that said packets of laser pulses reach said web (10), and engrave said pattern on said web as if said web were motionless.
Abstract:
The device for the treatment of the vaginal canal by a laser beam, comprises a vaginal canal wall retractor, associated to a system for directing the laser beam towards said wall.
Abstract:
A medical system for functional integration of at least one diagnosis device (21 - 27) and at least one surgical or therapeutic device (31 - 34) is described.
Abstract:
The equipment comprises a first laser source (3) adapted to emit a laser beam (F3) and a first output (1.3) which can be interfaced with an optical fiber (9), for conveying the first laser beam (F3) into the optical fiber (9). A deflector (11) moveable between a first inactive position and a second active position allows to direct the laser beam (F3) at least partially into a cladding (9.2) surrounding the core (9.1) of the optical fiber (9) interfaced with the first output (1.3).