Presented is a method and apparatus for aiding medical procedures. An apparatus includes a housing defining a first opening, a second opening, and a interior, and a first cleaning element maintained within the interior relative to the first opening, the first cleaning element comprising at least one cleaning agent operable to remove extraneous debris from an object. The apparatus further includes a second cleaning element maintained with the interior relative to the second opening, the second cleaning element comprising at least one cleaning material and at least one white reference material, the at least one cleaning material operable to remove debris from an object. The apparatus also includes a conduit defining a passage from a first end of the housing to a second end of the housing.

A tissue containment system includes a bag body, a member extending from the bag body and defining a channel, and a viewing window. The bag body at least partially defines an interior region configured to contain a loose tissue specimen and defines an opening sized to receive the loose tissue specimen. The bag body is configured such that a first portion of the bag body can be disposed in an abdominal cavity of a patient while a second portion of the bag body extends outside of the patient. The viewing window is at least partially transparent and provides a seal between the interior region of the bag body and an ambient environment. The channel of the member is configured to receive a tissue visualization device that can be used to view the interior region of the containment bag through the viewing window.

A system and associated method is used for warming an endoscope, laparoscope, or other such instrument to minimize fogging. A flexible pad has a length, a width and a periphery for wrapping around the instrument and a plurality of separate chambers defined through partitions. Each of the separate chambers includes an activation disc and a mixture of water and sodium acetate to generate heat through an exothermic reaction initiated through manual manipulation of the disc for that chamber. The pad is preferably made from two plastic sheets of substantially equal size, with the chambers being formed by heat-sealing or otherwise bonding the periphery of the sheets and the partitions. At least some of the partitions establish lengthwise and/or widthwise fold lines in the pad. At least one of the partitions may include a gap to facilitate fluid transfer of the mixture. The disc is preferably made of perforated stainless steel. A housing may be provided to contain the pad in sleeve form, and an optional heat-conductive tube may be used to receive the instrument around which the pad is wrapped.

An image capturing device comprises an elongated body, an imaging window coupled to a distal end of the elongated body, and a heat source within the elongated body. The heat source is configured to apply heat to the imaging window to remove condensation from or prevent condensation from forming on the imaging window.

An endoscope includes: a first lens located at a distal-most position, a part of the first lens being exposed outside; a movable lens barrel configured to be able to move, and configured to hold a movable lens disposed on a proximal end side with respect to the first lens; an actuator unit including a coil that drives the movable lens barrel and generates heat by receiving a supply of electric power; and a control section that outputs first electric power to the coil when holding the movable lens barrel at a predetermined position, and outputs second electric power larger than the first electric power to the coil when conducting heat generated from the coil to the first lens at the predetermined position.

The present disclosure relates to vision preservation systems for medical devices, such as cryospray devices for use with endoscopes. Exemplary embodiments provide a distal attachment in the form of a shroud or cap that mounts to the end of a flexible endoscope. A purging fluid supply mechanism is provided along the length of the endoscope, providing a channel for purging fluid, such as gas, to communicate between the endoscope tip and an external gas supply. The cap or shroud assembly incorporates a lens clearing flow field adjustment mechanism, such as nozzles, designed to direct warm (room temperature or higher) purging fluid across a lens at the scope tip. Another flow deflection mechanism, such as a guide or nozzle, may be included with the cap to direct purging fluid at an angle away from the lens. Gas, as an example, directed across and toward the lens purges moisture to avoid condensation on the lens and shears debris and bodily fluids away from the field of view. Gas directed or deflected by a guide away from the lens serves the purpose of keeping incoming particles and fluid droplets (e.g. spatter) from impacting on the lens cover. The cap and shroud are designed to avoid entraining moist air from the body cavity or lumen being treated.

A laparoscope/endoscope warmer includes a rechargeable heater with an inexpensive, disposable casing so that the expensive portions of the system can be reused. An elongated heater has an outer wall, a closed end and an open end into a cavity having an inner wall. A heating element such as a heating coil is disposed between the inner and outer walls of the heater. A rechargeable battery within the heater powers the heating element. The heater fits into a charging base operative to recharge the rechargeable battery through cooperating electrical contacts or an inductive coupling. The sterile casing includes an inner sleeve that fits into the cavity of the heater unit, providing a receptacle to receive and warm the rod of an endoscope or laparoscope.

A system for simultaneously heating multiple elongated surgical viewing instruments comprises a heater with a slot and an insert received by the slot. The insert has multiple elongate cavities, each configured to receive the tip of a viewing instrument. A cover, configured to cover the heater with the insert in the slot thereof, provides a plurality of openings aligned with the cavities of the insert. In the preferred embodiment, the heater is reusable and the insert and cover are disposable. The insert and cover may be integrally joined into a single unit. The system may further include a stand upon which the heater is supported, one or more cavities to receive cleaning swabs to be heated, and/or a pad to heat a cleaning wipe or other article.

A device having an optical element with a conductive coating. The device may include an optical element, a conductive material and at least one connector. The conductive material is disposed on at least a portion of the optical element. The optical element, for example, may be an object lens of an endoscope or an optical coupler. The connectors (acting as terminal(s)) are capable of providing energy (such as electrical energy) to the conductive material. In one aspect, the conductive material is an optically transparent material. Advantageously, the device may allow visualization of an object—such as body tissue or other matter—concurrent with the application of energy to the object via the conductive coating. This allows the user to observe the alteration of tissue and other matter in real time as the energy is delivered.

A camera system, particularly for minimally-invasive surgery, comprising an optics, wherein the optics is connected to at least one transparent film and the film is removable. Further, there is provided a method for cleaning a camera in minimally-invasive surgery wherein an optics of the camera is cleaned intracorporally by use of a cleaning device.