Extra-urethral implants and methods of use are disclosed. Implants can treat disorders or diseases of the prostate by, for example, enlarging the lumen of the prostatic urethra.

The present invention generally relates to the field of laser treatment of tissue, and particularly, to a system and method for creating microablated channels in skin. The present invention is more particularly directed to treating subsurface tissue through the created channels.

The presently disclosed subject matter provides techniques for inducing collagen cross-linking in human tissue, such as cartilage, by inducing ionization of the water contained in the tissue to produce free radicals that induce chemical cross-linking in the human tissue. In an embodiment, a femtosecond laser operates at sufficiently low laser pulse energy to avoid optical breakdown of the tissue being treated. In an embodiment, the femtosecond laser operates in the infrared frequency range.

A system for performing robotic laser surgery is disclosed. The system comprises at least one surgery equipment, a surgeon terminal, and a communication module. Further, the system includes a surgical computer communicatively coupled to the at least one surgery equipment via the communication module. The surgical computer is configured to transfer data between the surgeon terminal and the at least one surgery equipment. The surgeon terminal is configured to modulate the tunable laser to conduct the surgical procedure in fully autonomous mode or semi-autonomous mode using robot controls. Further, a plurality of sensors is used to real-time data while performing surgical procedure and transmit the real-time data to the surgeon terminal.

A system for performing robotic laser surgery is disclosed. The system comprises at least one surgery equipment, a surgeon terminal, and a communication module. Further, the system includes a surgical computer communicatively coupled to the at least one surgery equipment via the communication module. The surgical computer is configured to transfer data between the surgeon terminal and the at least one surgery equipment. The surgeon terminal is configured to modulate the tunable laser to conduct the surgical procedure in fully autonomous mode or semi-autonomous mode using robot controls. Further, a plurality of sensors is used to real-time data while performing surgical procedure and transmit the real-time data to the surgeon terminal.

The methods, procedures, kits, and devices described herein assist with the healing process of tissue that was previously or simultaneously treated for a therapeutic or cosmetic effect. The methods, procedures, kits, and devices described herein can also provide temporary simulated results of a cosmetic procedure to allow for visual assessment to select the type of procedure or for treatment planning in advance of the surgical procedure.

An ablation system comprises: an ablation catheter and a console. The ablation catheter comprises: a shaft including a proximal end, a distal portion and a distal end; an ablation element configured to deliver energy to tissue; and a force maintenance assembly comprising a force maintenance element and configured to control and/or assess contact force between the ablation element and cardiac tissue. The console is configured to operably attach to the ablation catheter and comprises: an energy delivery assembly configured to provide energy to the ablation element. Methods of ablating tissue are also provided.

The present invention uses one or more radiation-emitting devices in combination with a topical radiation block to ablate the skin and remove topographic variations in the skin surface. The energy pathway may be guided by a computer. The device might also include a treatment plate or window to be placed against the skin in order to flatten the skin surface during treatment. The purpose of the topical radiation block is to manage the areas to which the radiation is applied to the skin by allowing the radiation to reach some portions of the skin, while limiting or preventing the radiation from reaching other portions of the skin. In the case of atrophic scarring, for example, the block may be deposited selectively into the atrophic indentations, such that the block limits or prevents the radiation from reaching (and thereby ablating) the indentations, but allows the radiation to reach (and thereby ablate) the surrounding skin tissue. By ablating only the surrounding tissue, the z of the surrounding tissue is reduced, eventually minimizing or eliminating differences in the skin's topography between the indentations and the surrounding tissue. In the case of hypertrophic scarring, the block may be applied selectively to the surrounding tissue, such that the block limits or prevents the radiation from reaching (and thereby ablating) the scars, but allows the radiation to reach (and thereby ablate) the scars. By ablating only the scars, the z of the scars is reduced, eventually minimizing or eliminating differences in the skin's topography between the scars and the surrounding tissue.

The present invention uses one or more radiation-emitting devices in combination with a topical radiation block to ablate the skin and remove topographic variations in the skin surface. The energy pathway may be guided by a computer. The device might also include a treatment plate or window to be placed against the skin in order to flatten the skin surface during treatment. The purpose of the topical radiation block is to manage the areas to which the radiation is applied to the skin by allowing the radiation to reach some portions of the skin, while limiting or preventing the radiation from reaching other portions of the skin. In the case of atrophic scarring, for example, the block may be deposited selectively into the atrophic indentations, such that the block limits or prevents the radiation from reaching (and thereby ablating) the indentations, but allows the radiation to reach (and thereby ablate) the surrounding skin tissue. By ablating only the surrounding tissue, the z of the surrounding tissue is reduced, eventually minimizing or eliminating differences in the skin's topography between the indentations and the surrounding tissue. In the case of hypertrophic scarring, the block may be applied selectively to the surrounding tissue, such that the block limits or prevents the radiation from reaching (and thereby ablating) the scars, but allows the radiation to reach (and thereby ablate) the scars. By ablating only the scars, the z of the scars is reduced, eventually minimizing or eliminating differences in the skin's topography between the scars and the surrounding tissue.

Provided is a flex-PCB catheter device that is configured to be inserted into a body lumen. The flex-PCB catheter comprises an elongate shaft, an expandable assembly, a flexible printed circuit board (flex-PCB) substrate, a plurality of electronic components and a plurality of communication paths. The elongate shaft comprises a proximal end and a distal end. The expandable assembly is configured to transition from a radially compact state to a radially expanded state. The plurality of electronic elements are coupled to the flex-PCB substrate and are configured to receive and/or transmit an electric signal. The plurality of communication paths are positioned on and/or within the flex-PCB substrate. The communication paths selectively couple the plurality of electronic elements to a plurality of electrical contacts configured to electrically connect to an electronic module configured to process the electrical signal. The flex-PCB substrate can have multiple layers, including one or more metallic layers. Acoustic matching elements and conductive traces can be includes in the flex-PCB substrate.