The present invention is directed to systems, devices and methods for trans-septally delivering carbon dioxide through a minimally invasive catheter to create a gaseous pocket or emphysema between the posterior wall of the left atrium and the esophagus during cardiac ablation of the left atrium. This pocket of gas expanded tissue serves to thermally insulate and separate the esophagus from the left atrium during ablation to prevent the formation of an atrial-esophageal fistula. The system comprises a control system to precisely deliver the gas to a desired location through a needle-based catheter assembly.

Some embodiments of a medical device anchor system include an anchor device that receives a catheter (or other medical instrument) and secures the catheter in place relative to a skin penetration point. In some embodiments, the anchor device can secure the catheter in an operative position relative to the skin penetration point without use of suture or skin tapes.

Some embodiments of a medical device anchor system include an anchor device that receives a catheter (or other medical instrument) and secures the catheter in place relative to a skin penetration point. In some embodiments, the anchor device can secure the catheter in an operative position relative to the skin without the use of sutures or skin tapes. In particular embodiments, the anchor device can be adjusted to a folded condition so that subcutaneous anchors are partially rotated prior to removal from the skin penetration point.

Some embodiments of a medical anchor device include an elongate body coupled with deployable subcutaneous anchors to secure a catheter instrument (or other medical instrument) in place relative to a skin penetration point. In some circumstances, the elongate body may be in the form of catheter hub body, and the subcutaneous anchors can be deployed from the hub body by adjustment of a movable actuator. A locking member can interact with the actuator so as to retain the actuator in the deployed orientation during the medical procedure.

Enteric feeding tube housings configured to secure a feeding tube to the body are disclosed. The housing includes a disc having a hole configured to accommodate the feeding tube and two or more holes configured to accommodate fasteners. Also disclosed are enteric feeding tube housings that include a disc having a hole configured to accommodate the feeding tube and two or more holes configured to accommodate fasteners, and a plurality of fasteners. Also disclosed are surgical kits that include a housing, a plurality of fasteners, and a plurality of locking devices configured to adjustably secure the fasteners in the fastener receiving holes, and method of using the disclosed devices.

Some embodiments of a medical device anchor system include an anchor device that receives a medical instrument (such as a catheter or the like) and secures the instrument in place relative to a skin penetration point. In some circumstances, the anchor device may allow the anchor device to be used after medical instrument is already in place without the need for a second penetration point for the anchor device.

A device for releasably and adjustably securing a medical tube includes a receiver and a tail, which may be used for thoracostomy. The receiver has a receiver aperture and receiver teeth. The tail has center holes along a central axis of the device. Raised tail teeth are formed on the tail between the central axis and the tail sides. The tail teeth are arranged to engage the receiver teeth when an end of the tail is fed through the receiver aperture to form a tail loop. The receiver teeth define receiver teeth apertures that are smaller than the receiver aperture. The tail loop is adjustable to tighten around the medical tube.

Methods and apparatus for anchoring a catheter to a patient's skin using a catheter anchoring device are described. The catheter anchoring device includes one or more pairs of sharps with a sharpened end configured to pierce the surface of the skin. A locking mechanism for the sharps is used as a failsafe mechanism. The catheter anchoring device further includes a catheter clamp for securing a catheter to the catheter anchoring device. Releasing the clamp allows an operator to reposition and secure the catheter at the new position without moving the catheter anchoring device.

Some embodiments of a medical anchor device include an elongate body coupled with deployable subcutaneous anchors to secure a catheter instrument (or other medical instrument) in place relative to a skin penetration point. In some circumstances, the elongate body may be in the form of catheter hub body, and the subcutaneous anchors can be deployed from the hub body by adjustment of a movable actuator. A locking member can interact with the actuator so as to retain the actuator in the deployed orientation during the medical procedure.

Some embodiments of a medical device anchor system include an anchor device that receives a catheter (or other medical instrument) and secures the catheter in place relative to a skin penetration point. In some embodiments, the anchor device can secure the catheter in an operative position relative to the skin without the use of sutures or skin tapes. In particular embodiments, the anchor device can be adjusted to a folded condition so that subcutaneous anchors are partially rotated prior to removal from the skin penetration point.