Abstract: Systems and methods disclosed herein include a first scanner comprising an inflatable membrane configured to be inflated with a medium to conform an exterior surface of the inflatable membrane to an interior shape of a cavity, the medium attenuating, at a first rate per unit length, light having a first optical wavelength, and attenuating, at a second rate per unit length, light having a second optical wavelength; an emitter configured to illuminate an interior surface of the inflatable membrane; a detector configured to receive light from the interior surface; a processor configured to generate a first electronic representation of the interior shape based on the received light; and a design computer configured to modify the first electronic representation into a three-dimensional shape by correlating pixels of the first electronic representation with corresponding distance information from the first scanner to the inflatable membrane for each pixel.

Abstract: A system includes a first scanner comprising an inflatable membrane configured to be inflated with a medium to conform an exterior surface of the inflatable membrane to an interior shape of a cavity, the medium attenuating, at a first rate per unit length, light having a first optical wavelength, and at a second rate per unit length, light having a second optical wavelength. The system comprises an emitter and detector configured to generate and receive light from the interior surface of the inflatable membrane, respectively. A processor is configured to generate a first electronic representation of the interior shape and a second electronic representation of a second shape based on the received light. A design computer is configured to combine the first and second electronic representation into a combined electronic representation corresponding to at least a portion of the interior shape based on at least one or more native references.

Abstract: A control method is provided to manage a surgical robot having an arm configured to hold a medical tool. The method includes receiving a set of sensor signals from sensors on the arm, generating a profile based on the set of sensor signals, comparing the profile to at least one signature, determining a state of the arm based on results of the comparison, and changing operation of the arm based on the state of the arm. The state of the arm is indicative of a predetermined condition that has occurred or will likely occur eminently. Changing operation of the arm prevents the condition from occurring or continuing. The robot arm may hold a medical tool for using during surgery or another medical procedure.

Abstract: A surgical safety system for use in connection with a powered surgical instrument can be a standalone device or can be incorporated into existing electrosurgical instruments and generators. The system employs a controller connected to one or more sensors that are monitoring an aspect of a patient undergoing surgery. The controller is also in electrical communication with the powered surgical instrument and is configured to disable the instrument if movement or impending movement is detected.

Abstract: A system includes a first scanner comprising an inflatable membrane configured to be inflated with a medium to conform an exterior surface of the inflatable membrane to an interior shape of a cavity, the medium attenuating, at a first rate per unit length, light having a first optical wavelength, and at a second rate per unit length, light having a second optical wavelength. The system comprises an emitter and detector configured to generate and receive light from the interior surface of the inflatable membrane, respectively. A processor is configured to generate a first electronic representation of the interior shape and a second electronic representation of a second shape based on the received light. A design computer is configured to combine the first and second electronic representation into a combined electronic representation corresponding to at least a portion of the interior shape based on at least one or more native references.

Abstract: A robotic introducer system comprises a first assembly comprising a cable control assembly configured for use in a plurality of medical procedures, a second assembly comprising a distal link extension assembly configured for fewer uses than the first assembly, and a third assembly comprising an articulating probe assembly, coupled between the first and second assemblies and configured for fewer uses than the second assembly.

Abstract: A system includes an articulating probe, a surgical tool, and a controller. The controller is constructed and arranged to manipulate at least one of the articulating probe and the surgical tool. The system further includes a human interface device (HID) configured to generate a first control signal and a second control signal. The articulating probe is manipulated in response to the first control signal and the surgical tool is manipulated in response to the second control signal.

Abstract: A system includes a first scanner having an inflatable membrane configured to be inflated with a medium to conform an exterior surface of the inflatable membrane to an interior shape of a cavity. The medium attenuates, at first rate per unit length, light having a first optical wavelength, and attenuates, at a second rate per unit length, light having a second optical wavelength. An emitter is configured to generate light to illuminate the interior surface and a detector is configured to receive light from the interior surface. The scanner further includes a processor configured to generate a first electronic representation of the interior shape based on the light. A design computer is configured to modify the first electronic representation into a three-dimensional shape corresponding to at least a portion of the interior shape and a fabricator configured to fabricate, based at least on the modified first electronic representation, an earbud.

Abstract: A device for performing a procedure may include an elongate tube having a proximal end and a distal end and an adapted link having a proximal end and a distal end. The distal end may include a first mating surface, where the proximal end may be configured to attach to the distal end of the elongate tube. The device may also include a rotating link having a second mating surface configured to rotatably interface with the adapted link first mating surface.

Abstract: A steerable multi-linked device. The device includes a first multi-linked mechanism and a second multi-linked mechanism. The first mechanism defines a first plurality of grooves. The second mechanism defines a second plurality of grooves. The first and second pluralities of grooves cooperate to define at least two working ports along a length of the device. At least one of the first and second mechanisms are steerable.

Abstract: In an articulating probe system, an articulating probe is constructed and arranged to articulate in at least one degree of motion and to transition between a flexible state and a rigid state, the articulating probe comprising a plurality of links between a proximal link and a distal link. The distal link of the articulating probe includes a side port constructed and arranged to receive a distal end of an elongate tool. A tool support is in communication with the articulating probe for supporting the elongate tool, the tool support including a tool tube that extends from the tool support at an intermediate portion to the side port of the distal link at a distal portion, the tool tube having a first flexibility in the intermediate portion and having a second flexibility in the distal portion; the second flexibility being greater in flexibility than the first flexibility.

Abstract: A highly articulated robotic probe comprises an outer sleeve and an inner core. The outer sleeve and inner core include a plurality of links. The links of the outer sleeve and inner core are configured to pivot relative to one another. Various characteristics of the links determine the overall pivot angle of the articulated probe. Each of the plurality of links may have one or more channels. The channels form a semi-continuous passage from link to link and are configured to receive an elongated member such as an inner core, tool or cable. One or more cables may be used to control the outer links of the outer sleeve and the inner links of the inner core. Various characteristics of the cables determine the overall performance of the articulated probe.

Abstract: A highly articulated robotic probe comprises an outer sleeve and an inner core. The outer sleeve and inner core include a plurality of links. The links of the outer sleeve and inner core are configured to pivot relative to one another. Various characteristics of the links determine the overall pivot angle of the articulated probe. Each of the plurality of links may have one or more channels. The channels form a semi-continuous passage from link to link and are configured to receive an elongated member such as an inner core, tool or cable. One or more cables may be used to control the outer links of the outer sleeve and the inner links of the inner core. Various characteristics of the cables determine the overall performance of the articulated probe.

Abstract: A system includes a first scanner having an inflatable membrane configured to be inflated with a medium to conform an exterior surface of the inflatable membrane to an interior shape of a cavity. The medium attenuates, at first rate per unit length, light having a first optical wavelength, and attenuates, at a second rate per unit length, light having a second optical wavelength. An emitter is configured to generate light to illuminate the interior surface and a detector is configured to receive light from the interior surface. The scanner further includes a processor configured to generate a first electronic representation of the interior shape based on the light. A design computer is configured to modify the first electronic representation into a three-dimensional shape corresponding to at least a portion of the interior shape and a fabricator configured to fabricate, based at least on the modified first electronic representation, an earbud.

Abstract: A system for releasably attaching a steerable disposable multi-linked device to a durable device may include a disposable portion and a durable portion. The disposable portion may include a connecting member connected to the disposable portion and the durable portion and a steerable multi-linked device. The steerable multi-linked device may include a first link, a plurality of intermediate links, a second link movably coupled to a second one of the intermediate links, and a cable which passes through the first link and intermediate links and extends beyond a first end of the first link. A first one of the intermediate links may be movably coupled to the first link. The durable portion may include an axial member which defines an opening therethrough and a feeder mechanism.

Abstract: A system includes a first scanner having an inflatable membrane configured to be inflated with a medium to conform an exterior surface of the inflatable membrane to an interior shape of a cavity. The medium attenuates, at first rate per unit length, light having a first optical wavelength, and attenuates, at a second rate per unit length, light having a second optical wavelength. An emitter is configured to generate light to illuminate the interior surface and a detector is configured to receive light from the interior surface. The scanner further includes a processor configured to generate a first electronic representation of the interior shape based on the light. A design computer is configured to modify the first electronic representation into a three-dimensional shape corresponding to at least a portion of the interior shape and a fabricator configured to fabricate, based at least on the modified first electronic representation, an earbud.

Abstract: A system and method for performing a medical procedure includes a first multi-linked mechanism comprising a plurality of first links, and a lumen therethrough; a second multi-linked mechanism comprising a plurality of second links, wherein the second multi-linked mechanism is constructed and arranged to be slidingly received by the lumen of the first multi-linked mechanism, and where the first and second multi-linked mechanisms are configured to transition from a limp state to a rigid state; a set of proximal cables comprising at least a first proximal cable and a second proximal cable; a set of distal cables comprising at least a first distal cable and a second distal cable; a cable control assembly constructed and arranged to independently apply tension to the first proximal cable and the second proximal cable; a cable interface assembly constructed and arranged to receive a force from at least the first proximal cable and the second proximal cable and to transmit a corresponding force to at least the first

Abstract: An articulate probe device includes a first mechanism, a second mechanism, and an overtube mechanism. The first mechanism includes a proximal link which is movable coupled to a first intermediate link, a plurality or intermediate links, and a distal link which is moveably coupled to a second one of the intermediate links. The second mechanism includes a proximal link which is movable coupled to a first intermediate link, a plurality of intermediate links, and a distal link which is moveably coupled to a second one of the intermediate links. The overtube mechanism includes a proximal link which is movable coupled to a first intermediate link, a plurality of intermediate links, and a proximal link which is moveably coupled to a second one of the intermediate links. Further, at least one of the first mechanism, second mechanism, and overtube mechanism is steerable and extendable beyond the other mechanisms.

Abstract: An articulate probe device includes a first mechanism, a second mechanism, and an overtube mechanism. The first mechanism includes a proximal link which is movable coupled to a first intermediate link, a plurality or intermediate links, and a distal link which is moveably coupled to a second one of the intermediate links. The second mechanism includes a proximal link which is movable coupled to a first intermediate link, a plurality of intermediate links, and a distal link which is moveably coupled to a second one of the intermediate links. The overtube mechanism includes a proximal link which is movable coupled to a first intermediate link, a plurality of intermediate links, and a proximal link which is moveably coupled to a second one of the intermediate links. Further, at least one of the first mechanism, second mechanism, and overtube mechanism is steerable and extendable beyond the other mechanisms.

Abstract: A method includes applying a transferrable material to an outer surface of a casting plate to form a pattern on the outer surface of the casting plate. After applying of the transferrable material, a composite material is applied to the outer surface of the casting plate to form an inflatable membrane. The composite material covers at least a portion of the pattern and includes a florescent material and a pigment material. The inflatable membrane is cured to allow removal of the inflatable membrane from the casting plate. The inflatable membrane has an inner surface having the pattern detectable upon receiving of light causing the fluorescing material to emit florescent light.