A device for cooling a living tissue is disclosed. The cooling device solves severe patient's waiting and clinic work load due to time-consuming anesthesia required by conventional therapies. The cooling device also significantly reduces psychological burden and pain of the patient for ocular anesthesia. The cooling device includes a cooling unit configured to cool a target area and a heat dissipating unit configured to dissipate heat from the cooling unit. The heat dissipating unit is also configured to regulate internal air flow to increase heat dissipating efficiency.

A cooling device for removing heat from subcutaneous lipid-rich cells of a subject having skin is provided. The cooling device includes a plurality of cooling elements movable relative to each other to conform to the contour's of the subject's skin. The cooling elements have a plurality of controllable thermoelectric coolers. The cooling elements can be controlled to provide a time-varying cooling profile in a predetermined sequence, can be controlled to provide a spatial cooling profile in a selected pattern, or can be adjusted to maintain constant process parameters, or can be controlled to provide a combination thereof.

The heated forceps for Meibomian gland expression disclosed herein may comprise, at least, a forceps and a heating element. The treatment of Meibomian gland dysfunction is benefited by the application of heat to the Meibomian glands during therapeutic manual expression of meibum. The heated forceps for Meibomian gland expression are intended to supply such heat during the manual expression process so as to improve the efficacy of such treatments. The forceps may comprise any appropriate forceps known in the art, and the heating element may be removably attached to the forceps for ease of use and maintenance. In this way the forceps may also be made disposable, while the heating element is reusable.

Combined methods for treating a patient using time-varying magnetic field are described. The treatment methods combine various approaches for aesthetic treatment. The methods are focused on enhancing a visual appearance of the patient.

According to various embodiments, systems, devices and methods for modulating targeted nerve fibers (e.g., hepatic neuromodulation) or other tissue are provided. The systems may be configured to access tortuous anatomy of or adjacent hepatic vasculature. The systems may be configured to target nerves surrounding (e.g., within adventitia of or within perivascular space of) an artery or other blood vessel, such as the common hepatic artery.

An ablation device of a non-invasive radio-frequency ablation system includes a substrate having a first surface; a first electrode disposed on the first surface; a second electrode disposed on the first surface and adjacent to the first electrode; a moving unit electrically connected to the second electrode for moving the second electrode to regulate the distance between the second electrode and the first electrode; and a radio frequency generator connected to the ablation device for providing a radio frequency current to the first electrode and the second electrode. According to a method using the ablation device, the first and second electrodes are brought into contact with a third surface belonging to a subject in need of treatment, and the radio frequency current is applied to the electrodes to carry out a treatment procedure. The treatment depth and area are adjusted by changing the relative distance between the electrodes.

The present invention relates generally to surgical lasers and more specifically to a laser beam control and delivery system that accurately and efficiently directs a laser beam into an optical fiber. The laser beam control and delivery system also provides additional functions, including a connection for a fiber tip temperature control system and a tissue temperature sensing system. The present invention also relates to a surgical laser system that has a high efficiency thermoelectric cooling system.

An injection needle has an opening at a distal end thereof the injection needle and defines a hole. An optical fiber is configured to output a light from a light source and inserted in the hole. The optical fiber has a distal end positioned on an inner side of the opening. A protector is configured to transmit the light and is positioned further towards an opening side of the injection needle than the distal end. The protector is configured to prevent adherence of tissue to the optical fiber. The light emitted from the optical fiber is configured to irradiated onto a treatment target in a state in which the injection needle is inserted into skin, the distal end is positioned on an inner side of the opening, and the protector is positioned further towards the opening side of the injection needle than the distal end.

An electromagnetic beam scanning system and corresponding method of use is provided. The system includes a motor, a reciprocating mechanism, and a focus optic. The motor is configured to generate a rotational movement. The reciprocating mechanism is operatively coupled with the motor and configured to convert the rotational movement to a reciprocating movement including a plurality of strokes along a first scanned axis. The reciprocating movement has a constant speed over a portion of at least one stroke of the plurality of strokes. The focus optic is operatively coupled to the reciprocating mechanism such that the focus optic moves experiences the reciprocating movement of the reciprocating mechanism. The focus optic is configured to focus an electromagnetic radiation (EMR) beam incident upon the focus optic to a focus along an optical axis substantially orthogonal to the first scanned axis.

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.