A light based skin treatment device comprises a laser light source for providing a pulsed incident light beam for treating skin by laser induced optical breakdown of hair or skin tissue. In one arrangement, a focusing system has a pre-focusing lens for increasing the convergence of the an incident light beam and a skin contact lens having convex light input and light exit surfaces. The focal spot position is controlled by adjusting a spacing between the pre-focusing lens and the skin contact lens. In another arrangement, there is an adjustable lens system before an adjustable focusing system for providing compensation for aberration in the adjustable focusing system.

A scanning mechanism to scan a light source, such as a low-level laser, to create a desirable energy distribution on a treatment area. The light source may include multiple light beam generators, each having a different wavelength and each having a different energy distribution. The scanning mechanism can be programmable to scan in different patterns in accordance with a desired treatment.

A surgical laser system can include a fluorescent sensing assembly for detecting fluorescent signal from a tissue under a surgical operation of the surgical laser system. The surgical laser system can include an aiming laser assembly, which can be configured to provide excitation energy for the fluorescent process. The surgical laser system can include an infrared sensing assembly, which can provide temperature related data, for example, to prevent damages to the tissue due to overheating. The surgical laser system can be configured to use the off-time of the surgical laser for tissue sensing. Data from tissue sensing can be further analyzed by an integrated robotic surgical system to provide a highly precise surgical procedure.

Disclosed is a medical treatment apparatus. The medical treatment apparatus includes a magnetic resonance imaging (MRI) device, configured for imaging of a specific region including a target object and generating a magnetic resonance image; a laser interstitial thermal therapy (LITT) device, including an LITT probe, the LITT probe being positioned close to the target object based on the magnetic resonance image, and being configured to treat the target object by emitting laser; and a temperature measurement element, the temperature measurement element and the LITT probe being integrated as an integrated probe, and the temperature measurement element being configured to obtain a temperature of the target object.

Provided herein is a multifunctional aesthetic system including a housing, an electromagnetic array situated in the housing and having one or more electromagnetic radiation (EMR) sources, a controller in electronic communication with the array to operate the one or more of the EMR sources to direct the EMR beam to a treatment area, and one or more sensors in electronic communication with the controller for providing feedback to the controller based on defined parameters to allow the controller to adjust at least one operating condition of the multifunctional system in response to the feedback.

A hand-held laser treatment device automatically sweeps a line of laser energy across a treatment area of a patient without moving the device. Laser energy sources reside in a scan head housing, which is rotatably connected to a body housing at a housing mount. A motorized scanning mechanism in the body housing drives a pushrod connected that is to the scan head to cause the scan head to reciprocate about the housing mount axis, moving an emitted line of laser energy up and down. The scanning mechanism comprises a rotational motor, a pushrod drive cam, a guide cam and an amplitude adjustor, all coaxially aligned along a motor axis. Interposed between the pushrod drive cam and the guide cam are the pushrod and a guide bearing aligned along an axis parallel to the motor axis. The degree of sweep is adjustable to change the size of the area treated.

Embodiments of systems and methods for medical treatment using a series of pulsed lasers are disclosed. In an example, a system for medical treatment includes a laser source, an optical module, and a controller coupled to the optical module. The laser source is configured to generate a series of pulsed lasers. The optical module is configured to provide a series of focused laser spots on a patient based on the series of pulsed lasers. The controller is configured to control the at least one of the optical module and a stage for holding the patient to move the series of focused laser spots on the patient to form a scan pattern.

A system and method for increasing the amplitude of accommodation and/or changing the refractive power and/or enabling the removal of the clear or cataractous lens material of a natural crystalline lens is provided. Generally, the system comprises a laser, optics for delivering the laser beam and a control system for delivering the laser beam to the lens in a particular pattern. There is further provided a device for determining the shape and position of the lens with respect to the laser. There is yet further provided a method and system for delivering a laser beam in the lens of the eye in a predetermined shot pattern that utilize as series of shots that form a shell cut, a partial shell cut, a laser suture cut and/or a volumetric shaped removal, which essentially following the shape of a suture layer of the lens.

Resonance Raman scatter is used to differentiate in quasi-real time (QRT) anomalous tissue from adjacent normal tissue. The fingerprint generated from the tissue by a 1 second pulse of 532 nm emission for approximately one second is collected and is relayed by fiber-optic to a computerized controller that determines whether the target tissue is anomalous or normal. If anomalous it is ablated. This is performed by a pattern of Resonance Raman diagnostic emission and diagnostic sensor fibers. This diagnostic/therapeutic pattern of fibers can be moved by a joystick or robotically controlled. The data received by the computer is examined instantly, and should the site be diagnosed as anomalous, the optical biopsy/ablation is repeated immediately and repeated until the site is read as normal. Novel arrays of the diagnostic and therapeutic energies ensure a 3D anomalous tissue free zone around the removal site.

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.