Abstract: Embodiments of the invention include an endoscope including a distal chamber and related methods of use, for example, with an endoscopic instrument.

Abstract: An endoscopic imaging system includes a reusable control cabinet having a number of actuators that control the orientation of a lightweight endoscope that is connectable thereto. The endoscope is used with a single patient and is then disposed. The endoscope includes an illumination mechanism, an image sensor, and an elongate shaft having one or more lumens located therein. An articulation joint at the distal end of the endoscope allows the distal end to be oriented by the actuators in the control cabinet. The endoscope is coated with a hydrophilic coating that reduces its coefficient of friction and because it is lightweight, requires less force to advance it to a desired location within a patient.

Abstract: An endoscopic imaging system for examining a patient's body cavity includes an endoscope having a distal end, a proximal end and a number of lumens therein. One or more distal gas ports are disposed at or adjacent the distal end of the endoscope and one or more proximal gas ports are disposed proximal to the distal gas ports. Insufflation gas is delivered to the distal gas ports and withdrawn from the proximal gas ports or vice versa such that a gas bubble is formed in the body cavity and travels with the distal tip of the endoscope.

Abstract: An endoscopic imaging system for examining a patient's body cavity includes an endoscope having a distal end, a proximal end and a number of lumens therein. One or more distal gas ports are disposed at or adjacent the distal end of the endoscope and one or more proximal gas ports are disposed proximal to the distal gas ports. Insufflation gas is delivered to the distal gas ports and withdrawn from the proximal gas ports or vice versa such that a gas bubble is formed in the body cavity and travels with the distal tip of the endoscope.

Abstract: A shaft for a medical device includes an outer sheath and a flexible spiral wrap therein. The flexibility of the spiral wrap is modified by changing the width of the wraps of a spiral, the thickness of the wraps of a spiral, or the gap spacing of the spiral. The spacing between wraps is maintained by attaching the spiral wrap to the cover sheath that surrounds the spiral wrap at two or more locations.

Abstract: An apparatus and method for improved control of low viscosity fluid flow during electrohydrodynamic spray deposition of the fluid to coat small targets, such as medical devices like stents. The apparatus includes a target holder which applies a first electrical potential to a target, a coating fluid transporter such as a wick, a siphon tube or a siphon tube with a wick therein along which the coating fluid flows from a reservoir to a dispensing end of the transporter, and an electrode which applied a second electrical potential to the coating fluid sufficient to cause the coating fluid to be attracted from the dispensing end of the transporter toward the target. This provides a target coating apparatus with highly self-regulating coating fluid flow characteristics despite the low viscosity of the coating fluid, while producing highly consistent and uniform target coatings.

Abstract: In one aspect, the present invention is a system for rotatably coupling a shaft to a housing. The system includes a selectively rotatable shaft coupler that connects a shaft to a housing that allows a limited amount of shaft rotation, but which sets a restriction on the maximum amount of shaft rotation. In another aspect, the invention provides a shaft coupling system for connecting a proximal end of an endoscope shaft to a housing without the use of adhesive or epoxies.

Abstract: A system and method for orienting an endoscope shaft and operator control module. The operator control module includes an engaging mechanism that allows the operator control module to be disengaged from the endoscope shaft. This allows the operator control module to remain in the operator's preferred orientation and then be re-engaged to the endoscope shaft. Remotely powered tip articulation cables are also provided, thus allowing the operator control module the freedom of not having to remain mechanically attached to the endoscope shaft in a fixed position. When the operator wants to rotate the endoscope shaft axially and does not want the position of the operator control module to be changed, the operator control module engaging mechanism is disengaged, after which the endoscope shaft is rotated to the desired position, and the engaging mechanism is then re-engaged to the endoscope shaft or to a fixed feature on the shaft.

Abstract: System and method for coating a medical appliance are provided. In accord with one embodiment, a system for applying a coating to a medical appliance having accessible patterned surfaces is provided. The system may include: a processor, an appliance support, and a solenoid type fluid dispensing head having an electromagnetically controlled valve. In the system, the appliance support may be adapted to hold the medical appliance and to provide direct access for a coating to contact the exposed external patterned surfaces of the medical appliance. The solenoid type fluid dispensing head in this system may move with respect to the medical appliance and may be in communication with a source of coating and with the processor. The processor in this system may contain commands that instruct the solenoid type fluid dispensing head to force coating onto the accessible patterned surfaces of the medical appliance in a pattern that correlates with the accessible patterned surfaces of the medical appliance.

Abstract: The present invention provides an apparatus and method that uses positive displacement of coating material using a computer controlled, motorized dispensing device. The flow rate of the dispensing device is controlled, and the positive displacement apparatus and method result in a precise amount of coating that is dispensed. The positive displacement coating apparatus and method allow for much more accurate and consistent coating from part to part. Because the positive displacement coating apparatus precisely controls the flow rate of the coating, differences in viscosity of the coating do not adversely affect the amount of the coating that is dispensed. In addition, the fluid flow path or pressure differential do not adversely affect the amount of the coating that is dispensed.

Abstract: A system and method for selective masking of stents using an expandable masking balloon to prevent deposition of therapeutic or protective coatings on portions of the stent during a coating application process. An expandable balloon is located within the inner region of a stent, the balloon is inflated until its outer surface contacts and the inner surface of the stent lattice in the areas in which the stent coating is not to be applied, thereby masking the stent inner surface from deposition of stent coating material during a stent coating process, and the coating is applied to the remaining exposed surfaces of the stent, for example by spraying or dipping the stent. The balloon is then deflated and removed from the coated stent. The balloon may be coated with, or formed from, a material impregnated with polytetrafluoroethylene to discourage adherence of the coating material to the balloon's outer surface in order to minimize coating waste and bridging of stent lattice openings by coating films.

Abstract: An apparatus and method for improved control of low viscosity fluid flow during electrohydrodynamic spray deposition of the fluid to coat small targets, such as medical devices like stents. The apparatus includes a target holder which applies a first electrical potential to a target, a coating fluid transporter such as a wick, a siphon tube or a siphon tube with a wick therein along which the coating fluid flows from a reservoir to a dispensing end of the transporter, and an electrode which applied a second electrical potential to the coating fluid sufficient to cause the coating fluid to be attracted from the dispensing end of the transporter toward the target. This provides a target coating apparatus with highly self-regulating coating fluid flow characteristics despite the low viscosity of the coating fluid, while producing highly consistent and uniform target coatings.

Abstract: A control mechanism for automatically steering the distal end of an endoscope into a body cavity. During advancement of the endoscope, the control mechanism directs the distal tip to be moved in a sweep pattern. Images obtained during the sweep pattern are combined and analyzed in order to determine the desired direction of advancement of the endoscope. The distal end of the endoscope is then oriented in the direction of the desired advancement direction. An autoexamination feature can be activated that automatically moves the distal tip in a desired sweep pattern. Images of a body cavity are obtained during each sweep pattern for analysis by the physician.

Abstract: An endoscopic imaging system includes a reusable control cabinet having a number of actuators that control the orientation of a lightweight endoscope that is connectable thereto. The endoscope is used with a single patient and is then disposed. The endoscope includes an illumination mechanism, an image sensor and an elongate shaft having one or more lumens located therein. A polymeric articulation joint at the distal end of the endoscope allows the distal end to be oriented by the control cabinet. The endoscope is coated with a hydrophilic coating that reduces its coefficient of friction and because it is lightweight, requires less force to advance it to a desired location within a patient.

Abstract: System and method for coating a medical appliance is provided. In accord with one embodiment, a system for applying a coating to a medical appliance having accessible patterned surfaces is provided. The system may include: a processor, an appliance support, and a solenoid type fluid dispensing head having an electromagnetically controlled valve. In the system, the appliance support may be adapted to hold the medical appliance and to provide direct access for a coating to contact the exposed external patterned surfaces of the medical appliance. The solenoid type fluid dispensing head in this system may move with respect to the medical appliance and may be in communication with a source of coating and with the processor. The processor in this system may contain commands that instruct the solenoid type fluid dispensing head to force coating onto the accessible patterned surfaces of the medical appliance in a pattern that correlates with the accessible patterned surfaces of the medical appliance.

Abstract: The present invention relates to microarray polymeric barriers designed to control the release rate of therapeutic agents. By varying the thickness of the coating or affecting, physically and/or chemically, the constituents of the barrier composition, the release profile of the underlying therapeutic agent can be modified and controlled.

Abstract: System and method for coating a medical appliance are provided. In accord with one embodiment, a system for applying a coating to a medical appliance having accessible patterned surfaces is provided. The system may include: a processor, an appliance support, and a solenoid type fluid dispensing head having an electromagnetically controlled valve. In the system, the appliance support may be adapted to hold the medical appliance and to provide direct access for a coating to contact the exposed external patterned surfaces of the medical appliance. The solenoid type fluid dispensing head in this system may move with respect to the medical appliance and may be in communication with a source of coating and with the processor. The processor in this system may contain commands that instruct the solenoid type fluid dispensing head to force coating onto the accessible patterned surfaces of the medical appliance in a pattern that correlates with the accessible patterned surfaces of the medical appliance.

Abstract: System and method for coating a medical appliance is provided. In accord with one embodiment, a system for applying a coating to a medical appliance having accessible patterned surfaces is provided. This system may include: a processor, a support, and a bubble jet printing head having individual printing nozzles. In this system the support may be adapted to hold the medical appliance and to provide direct access for a coating to contact the exposed external patterned surfaces of the medical appliance. The bubble jet printing head in this system may move with respect to the medical appliance and may be in communication with a source of coating and with the processor. The processor in this system may contain commands that instruct the bubble jet printing head to force coating onto the accessible patterned surfaces of the medical appliance in a pattern that correlates with the accessible patterned surfaces of the medical appliance.

Abstract: System and method for coating a medical appliance is provided. In accord with one embodiment, a system for applying a coating to a medical appliance having accessible patterned surfaces is provided. The system may include: a processor, an appliance support, and a solenoid type fluid dispensing head having an electromagnetically controlled valve. In the system, the appliance support may be adapted to hold the medical appliance and to provide direct access for a coating to contact the exposed external patterned surfaces of the medical appliance. The solenoid type fluid dispensing head in this system may move with respect to the medical appliance and may be in communication with a source of coating and with the processor. The processor in this system may contain commands that instruct the solenoid type fluid dispensing head to force coating onto the accessible patterned surfaces of the medical appliance in a pattern that correlates with the accessible patterned surfaces of the medical appliance.

Abstract: System and method for coating a medical appliance is provided. In accord with on embodiment, a system for applying a coating to a medical appliance having accessible patterned surfaces is provided. This system may include: a processor, a support, and a bubble jet printing head having individual printing nozzles. In this system the support may be adapted to hold the medical appliance and to provide direct access for a coating to contact the exposed external patterned surfaces of the medical appliance. The bubble jet printing head in this system may move with respect to the medical appliance and may be in communication with a source of coating and with the processor. The processor in this system may contain commands that instruct the bubble jet printing head to force coating onto the accessible patterned surfaces of the medical appliance in a pattern that correlates with the accessible patterned surfaces of the medical appliance.