A surgical system includes an external anchor, an internal anchor and an instrument. The external anchor is adapted to be positioned outside a body. The internal anchor is adapted to be inserted into the body via a single entrance port, positioned inside the body and magnetically coupled with the external anchor. The instrument is adapted to be inserted into the body via the single entrance port and secured to the internal anchor. The instrument includes an end-effector that has multiple degrees of movement via multiple axes.

An in vivo capsule has a cauterization element that may be deployed by physician while in vivo for cauterizing a lesion, such as bleeding. Energy is transferred from outside of the patient's body to the capsule and specifically to the ablating element, such as via a resonance circuit. Accordingly, it is the object of the present invention to provide a method and apparatus for precisely cauterizing or ablating tissue in-vivo. Embodiments of the invention may provide an in-vivo device having a cauterization or ablation element incorporated therein and a system and method for controlled navigation of the in-vivo cauterization device through a body lumen.

New nanotechnology and other small-scale devices for performing intravenous medical procedures are provided. In some aspect of the invention, a group of encapsulated injectable machines is delivered intravenously into a bloodstream via a syringe. A treatment area within a patient's body is specified and targeted for action by an external control system, which also monitors blood flow and other environmental. Externally applied magnetic and/or electrostatic signaling and direction devices controlled by the control system then trigger the release of encapsulation layers surrounding the injectable machines upon reaching the treatment area. The externally applied magnetic signaling and direction devices then drive the machines into treatment targets within the treatment area, exploiting an overall charge and polarity of the machines distinct from their condition during encapsulation. Pulsed magnetic fields then cause polarized moving parts within the machines to move counter to one another, with opposing angled edges breaking up the treatment target. In some embodiments, the machines may also or alternatively deliver a magnetically- or electrostatically-released medication or device to the treatment target. In still other embodiments, a local control unit within the devices may direct additional, more sophisticated actions, which actions may be directed or triggered by external signaling from the externally-applied magnetic signaling and direction devices, or other aspects of the external control system.

A method of actuating a surgical device is described. A surgical tool is inserted into a body cavity of a patient through a natural orifice. A distal end of an actuation tool is inserted through a surgical access port in the body of the patient. The distal end of the actuation tool is positioned proximal to an external wall of the body cavity opposite the surgical tool. A magnetic coupling is established between the distal end of the actuation tool and the surgical tool. When the magnetic coupling is established, distal end of the actuation tool is located at the external wall of the body cavity and the surgical tool is located at the internal wall of the body cavity. The surgical tool is manipulated using the actuation tool through the magnetic coupling.

A percutaneous catheter system for use within the human body and an ablation catheter for ablating a selected tissue region within the body of a subject. The percutaneous catheter system can include two catheters that are operatively coupled to one another by magnetic coupling through a tissue structure. The ablation catheter can include electrodes positioned within a central portion. The ablation catheter is positioned such that the central portion of a flexible shaft at least partially surrounds the selected tissue region. Each electrode of the ablation catheter can be activated independently to apply ablative energy to the selected tissue region. The ablation catheter can employ high impedance structures to change the current density at specific points. Methods of puncturing through a tissue structure using the percutaneous catheter system are disclosed. Also disclosed are methods for ablating a selected tissue region using the ablation catheter.

A medical device (10), preferably a micro robot for application inside a body, and more preferably for application inside a human body (2). The medical device (10) includes a body part (11) and a tail part (12). A recapture line (13) is attached to the tail part (12). The recapture line (13) has a tensile strength which is sufficient to pull back the device while the column strength of the recapture line (13) not sufficient to push the medical device (10).

A control device for a capsule endoscope is provided. The control device includes a balance arm device, a permanent magnet, a 2-DOF rotary platform and an examination bed. The bottom of the balance arm device is fixed, and the active end of the balance arm device connects with a boom. The 2-DOF rotary platform is fixed below the boom and the permanent magnet is located in the 2-DOF rotary platform. The examination bed is put below the 2-DOF rotary platform, and the area between the examination bed and the 2-DOF rotary platform is an examination area.

A flow directed device adapted to be guided by a fuid, such as blood, flow within a tubular structure such as a blood vessel is disclosed, said device comprising a proximal end (100), a distal end (101) and an elongated body (102) in between defining a longitudinal axis (103), characterized in that said distal end (101) comprises a ferromagnetic area or structure (300) capable of deflecting the distal end (101) when subjected to an external magnetic field. A system comprising the device, as well as method of use of the device, are also disclosed.

Various embodiments of a system and method for controlling the shape, subdivision, recombination, movement and object manipulation of ferrofluid material in addition to pumping fluids with ferrofluid material using external electromagnetic fields are disclosed herein.

A cannula mounting fixture may include a base, a first arm with a first cannula mounting bracket and a second arm with a second cannula mounting bracket. The first arm may be coupled to the base so that a first cannula mounted at the first mounting bracket is positioned within an opening in a patient's body. The second arm may be coupled to the base and includes a joint that allows a second cannula mounted at the second mounting bracket to be inserted through the opening. A cannula stabilizing fixture may include a base and a repositionable arm. The base may be configured to be securely and removably coupled to a first cannula that extends into an opening in a patient's body. The repositionable arm may include a first cannula holder coupled to the base and is configured to support a second cannula that extends into the opening.