A medical probe includes a shaft, a camera, a hollow cutting tool, and an inflatable balloon. The shaft is configured for insertion through a cut in a body of a patient, whereas the shaft includes a working vacuum channel running therethrough. The camera is fitted at a distal end of the shaft and is configured to provide images of a target tissue site in the body. The hollow cutting tool is for insertion over a guidewire in the working vacuum channel of the shaft, whereas the hollow cutting tool is configured to pierce the target tissue site under guidance of images taken by the camera. The inflatable balloon is configured to stabilize the distal end of the shaft, whereas the inflatable balloon is located proximally to the camera so as not to obstruct the images of the target tissue site.

A system includes a processor and an output device. The processor is configured to: (a) receive electrical signals indicative of measured positions of (i) one or more chest position sensors attached externally to a chest of a patient, and (ii) one or more back position sensors attached externally to a back of the patient; (b) compare between (i) a first shift between the measured positions and respective predefined positions of the one or more chest position sensors, and (ii) a second shift between the measured positions and respective predefined positions of the one or more back position sensors; and (c) produce an alert in response to detecting a discrepancy between the first and second shifts. The output device is configured to output the alert to a user.

A system and method for transmyocardial laser revascularization (TMLR) in patients in need thereof, such as patients suffering from coronary artery disease. The system includes a Laser unit, an Electrocardiogram (EKG) unit, Vectorcardiography (VCG) unit, an Echocardiography unit, a spectrum Infrared sensor unit, and a control unit. The control unit can receive investigational data from different units and use the same to optimize the laser parameters. The Control unit can further include an AI module that can further analyze patient-related data, such as age and medical condition to further optimize the laser parameters. The laser unit can operate based on the optimized parameters to prevent unnecessary damage to the heart and allow maintaining the patency of the channels made by the laser for a longer duration.

Methods and apparatus are provided to facilitate the minimally invasive removal of tissue biopsies and to facilitate the direct approach to anesthetizing the chest wall, in accordance with embodiments of the present invention. A pull-type cutting device 1 comprises two coaxially nested tubes, each extending from a proximal end 21 to a distal end 22. The first tube 61 defines a guide wire lumen 23 for slidingly receiving a guide wire. The second tube 63 extends over the first tube 60 and coupled thereto at the distal end 22 defining an expandable portion 13 adjacent the distal end 22. The second tube 63 defines an inflation lumen 25 extending from the shaft proximal end 21 to the expandable portion 13. The inflation lumen 25 communicates inflation fluid from the proximal end 21 to the expandable portion 13 so as to inflate and deploy the expandable portion 13. Disposed adjacent the shaft distal end 22 is a cutting head 10 comprising the expandable portion 13 having a cutting portion 11 distal from the shaft distal end 22.

A method for reducing left ventricular volume, which comprises identifying infarcted tissue during open chest surgery; reducing left ventricle volume while preserving the ventricular apex; and realigning the ventricular apex, such that the realigning step comprises closing the lower or apical portion of said ventricle to achieve appropriate functional contractile geometry of said ventricle in a dyskinetic ventricle of a heart.

A method for implanting a replacement heart valve within a diseased valve includes accessing a patient's heart by piercing a myocardium, advancing a guidewire into the patient's heart, and installing an access device in a wall of the heart. The access device preferably has at least one valve mechanism. A valve delivery device is advanced over the guidewire and through the access device. The valve delivery device has a replacement heart valve disposed along a distal end portion thereof. The replacement heart valve preferably includes an outer support structure and a leaflet valve disposed within the outer support structure. The replacement heart valve is radially expanded within the diseased valve. During implantation, the outer support structure conforms to a diameter of the diseased valve and the leaflet valve expands to a fixed size having a diameter smaller than the diameter of the diseased valve.

Engagement catheter devices, systems, and methods to use the same under suctional tissue engagement. A method of the present disclosure comprises the steps of engaging a targeted tissue under suction/vacuum using an engagement catheter, delivering a substance to, into, or through the targeted tissue from within a lumen of the engagement catheter, and injecting a fluid within a different lumen of the engagement catheter to flush the catheter and target tissue area with the fluid, and subsequently suctionally removing the injected fluid from the target area and lumens of the engagement catheter.

Methods and apparatus are provided to facilitate the minimally invasive removal of tissue and to facilitate the direct approach to anesthetizing a body wall of a patient. A pull-type cutting device also is disclosed to introduce an opening into the body wall to provide access for intra-chest surgical interventions, for example a minimally invasive biopsy technique as also described for excising target tissue from within a patient, including a nodule from within the patient's lung.

A method for implanting a replacement heart valve within a diseased valve includes accessing a patient's heart by piercing a myocardium, advancing a guidewire into the patient's heart, and installing an access device in a wall of the heart. The access device preferably has at least one valve mechanism. A valve delivery device is advanced over the guidewire and through the access device. The valve delivery device has a replacement heart valve disposed along a distal end portion thereof. The replacement heart valve preferably includes an outer support structure and a leaflet valve disposed within the outer support structure. The replacement heart valve is radially expanded within the diseased valve. During implantation, the outer support structure conforms to a diameter of the diseased valve and the leaflet valve expands to a fixed size having a diameter smaller than the diameter of the diseased valve.

Engagement catheter devices, systems, and methods to use the same under suctional tissue engagement. A method of the present disclosure comprises the steps of engaging a targeted tissue under suction/vacuum using an engagement catheter, delivering a substance into or through the targeted tissue using a needle positioned within a first lumen of the engagement catheter, injecting a fluid within the first lumen of the engagement catheter to flush at least part of the first lumen with the fluid, and suctionally removing the injected fluid from within the first lumen of the engagement catheter.