An imaging system includes an image generating device and two reflecting mirrors. The image generating device projects a light toward a gravity direction. The two reflecting mirrors are disposed with respect to each other and one of the two reflecting mirrors is disposed with respect to the image generating device. The light projected by the image generating device forms a virtual image through the two reflecting mirrors in sequence.

The present invention relates to a flexible surgical system for endoscopic spinal decompression and methods thereof. Various methods of accessing the epidural space with this instrument are described. The system design enables placement of the device through several approaches. It is then advanced under direct visualization or fluoroscopic (X-Ray), for example, into areas of the spine including lumbar (low back), thoracic (mid and upper back) and cervical (neck). The pathologies encroaching upon the spinal space can then be visualized wherein the epidural membrane can optionally be displaced to further aid in visualization. The membrane can be used to protect regions of tissue adjacent the site to tissue removal.

Described herein are loupes shields. The shields can be easily attached to the loupes. The loupes shield is composed of a single filter that blocks harmful light. Additionally, the loupes shield includes a connector that permits the loupes shield to be attached to the loupes lens or housing that holds the loupes lens. The loupes shields described are useful in applications where it is desirable to protect the user from being exposed to damaging light. The loupes shields are useful in dental applications such as, for example, dental restorations, where light cure is required to cure the resin applied to a tooth during a dental restoration.

The present invention relates to a flexible surgical system for endoscopic spinal decompression and methods thereof. Various methods of accessing the epidural space with this instrument are described. The system design enables placement of the device through several approaches. It is then advanced under direct visualization or fluoroscopic (X-Ray), for example, into areas of the spine including lumbar (low back), thoracic (mid and upper back) and cervical (neck). The pathologies encroaching upon the spinal space can then be visualized wherein the epidural membrane can optionally be displaced to further aid in visualization. The membrane can be used to protect regions of tissue adjacent the site to tissue removal.

Visualization and ablation systems and catheters. The systems can capture a plurality of different 2D images of the patient's anatomy adjacent an expandable member, each of which visualizes at least one part of the patient that is in contact with the expandable membrane, tag each of the plurality of different 2D images with information indicative of the position and orientation of a locational element when each of the plurality of different 2D images was captured, create a patient map, wherein creating the patient map comprises placing each of the plurality of different 2D images at the corresponding tagged position and orientation into a 3space, and display the patient map.

A disposable material, pre-cut to various shapes or able to be cut or shaped at the time of use, to protect non-target tissue, excluding the eyes, during treatment of the skin is disclosed. The disposable material comprises a flexible material comprising at least one first layer comprising a material that mitigates the transmission of electromagnetic radiation from an radiation source; a backing layer that is located on top of the first layer and is configured to diffusively reflect the electromagnetic radiation without direct specular reflection; and an adhesive for removably attaching the disposable material to the skin. There is also disclosed a method of protecting non-target tissue, excluding the eyes, by applying the disclosed material to a desired location.

Visualization and ablation systems and catheters. The systems can capture a plurality of different 2D images of the patient's anatomy adjacent an expandable member, each of which visualizes at least one part of the patient that is in contact with the expandable membrane, tag each of the plurality of different 2D images with information indicative of the position and orientation of a locational element when each of the plurality of different 2D images was captured, create a patient map, wherein creating the patient map comprises placing each of the plurality of different 2D images at the corresponding tagged position and orientation into a 3 space, and display the patient map.

An ablation catheter including an elongate shaft, an inflatable balloon positioned at a distal region of the elongate shaft, a first ablation electrode disposed outside of and carried by an outer surface of the inflatable balloon, a first ultrasound transducer disposed outside of the inflatable balloon, and a flexible circuit. The flexible circuit includes a first conductor and a second conductor and is disposed outside of and carried by the outer surface of the inflatable balloon. The first conductor is in electrical communication with the first ablation electrode, and the second conductor in electrical communication with the first ultrasound transducer.

An ablation catheter includes an elongate shaft and an inflatable ablation member. The inflatable ablation member includes a flexible circuit with a conductor in electrical communication with an ablation electrode. The flexible circuit is disposed outside of and carried by an outer surface of an inflatable balloon. The inflatable ablation member includes an ultrasound monitoring member configured for use in monitoring at least one aspect of tissue ablation with the ablation electrode.

Apparatus comprising an ultrasound ablation system, which comprises a reflection-facilitation element, configured to be placed at an extramyocardial site of a subject, and to provide an extramyocardial reflective region; and an ultrasound tool, which comprises at least one ultrasound transducer configured to be positioned within a heart chamber of the subject. The ultrasound transducer is configured to ablate myocardial tissue by applying ultrasound energy to the myocardial tissue such that at least a portion of the transmitted energy is reflected by the reflective region onto the myocardial tissue. Other embodiments are also described.