Disclosed are formulations comprising epinephrine, a degradable polymer, and, in some embodiments, a mucoadhesive compound, and methods of their use for preventing or controlling gastrointestinal bleeding and for facilitating endoscopic interventions for separating diseased tissue from normal tissue. Also disclosed in an endoscopic needle for administering the formulations.

Intravascular devices and methods for intramural delivery of dissection fluids and infusates are disclosed herein. In some embodiments, the systems include an infusion assembly that can access a position in vessel adjacent an infusion site and advance a tissue manipulation component into the infusion site to deliver a therapeutic infusate. The infusion site can be an intraluminal space, such as within an obstructive material, adjacent the obstructive material, and/or within a boundary layer between the obstructive material and a vessel wall. The infusion assembly can further deliver an infusate that includes a therapeutic drug or other agent into the infusion site.

A rectal injection device and a method of operating a rectal injection device. In one embodiment, the device includes: (1) a handle having a trigger associated therewith, (2) an extension tube extending from the handle and terminating in a head, (3) at least two needles coupled to the head and configured to move relative thereto between a retracted position and a deployed position and (4) a pullrod coupling the trigger and the needles and configured to cause the needles to move.

The present invention describes a method for performing a prostate surgical treatment, said method comprising: arranging a catheter 1 inside of a urethra of a patient and anchored against the bladder neck of the patient subsequent to the filling of the balloon stopper unit 5 with a fluid when the balloon stopper unit 5 is arranged inside of the bladder of a patient;
said method also comprising injecting at least one anesthetic agent and adrenaline or injecting botulinum toxin (Botox) and/or penicillin to the prostate via the injection tube 9 and the hollow tip 10 at an intended position of the prostate.

Moreover, the present invention also refers to a kit comprising a catheter 1 according to the present invention and one or more syringe(s) 1000 containing adrenaline and at least one anesthetic agent and/or at least a syringe 1000 or vial containing botulinum toxin (Botox) and/or penicillin.

Intravascular devices and methods for intramural delivery of dissection fluids and infusates are disclosed herein. In some embodiments, the systems include an infusion assembly that can access a vessel wall at a depth within a layer of the vessel wall and advance a tissue manipulation component at approximately the same depth within the vessel wall to create an intramural space within the vessel layer. The infusion assembly can further deliver an infusate that includes a therapeutic drug or other agent into the intramural space.

A steerable endoscope system includes a continuum manipulator, a plurality of syringes, and a steerable tip. The continuum manipulator includes a plurality of spaced discs and a plurality of backbones each extending through all discs. A bending movement of the continuum manipulator changes a varying linear displacement of each backbone. Each backbone is further coupled to a different one of the syringes such that the linear displacement of each backbone pushes or pulls a piston of the corresponding syringe by a varying amount. The steerable tip includes a plurality of bellows each pneumatically coupled to a different syringe such that movement of the piston of a syringe causes the corresponding bellow to inflate or deflate. Because the distal end of each bellow is fixedly coupled to the same end effector, variations in the amount of inflation or deflation on each bellow causes a bending of the steerable tip.

A catheter-based/intravascular fluid injection system with application to renal denervation includes a multiplicity of needles which expand open around a central axis to engage the wall of a blood vessel, or the wall of the left atrium, allowing the injection of a cytotoxic and/or neurotoxic solution for ablating conducting tissue, or nerve fibers around the ostium of the pulmonary vein, or circumferentially in or just beyond the outer layer of the renal artery. The expandable delivery system includes expandable components that facilitate positioning of a multiplicity of injection needles against the inside wall of a blood vessel from where they can be advanced. The system also includes means to limit and/or adjust the depth of penetration of the ablative fluid into the tissue of the wall of the targeted blood vessel.

A catheter-based/intravascular fluid injection system with application to renal denervation includes a multiplicity of needles which expand open around a central axis to engage the wall of a blood vessel, or the wall of the left atrium, allowing the injection of a cytotoxic and/or neurotoxic solution for ablating conducting tissue, or nerve fibers around the ostium of the pulmonary vein, or circumferentially in or just beyond the outer layer of the renal artery. The expandable delivery system includes expandable components that facilitate positioning of a multiplicity of injection needles against the inside wall of a blood vessel from where they can be advanced. The system also includes means to limit and/or adjust the depth of penetration of the ablative fluid into the tissue of the wall of the targeted blood vessel.

A rectal injection device configured to inject a liquid into the tissues around the internal anal sphincter of a rectum. The rectal injection device comprises: i) an elongated tube having a distal end and a proximal end; ii) a rounded head coupled to the distal end of the elongated tube; iii) a needle extending from the proximal end of the elongated tube into the rounded head, wherein a tip of the needle is aligned with a hole in the rounded head; and iv) an actuator mechanism configured to move the needle to a deployed position in which the tip of the needle extends through the hole and into the anal tissues and to move the needle to a retracted position in which the tip of the needle is withdrawn within the rounded head.

A microneedle skin care device includes a housing having a predetermined space formed therein; a sound wave module disposed inside the housing to provide sound wave vibration; a microneedle assembly configured to receive vibration of the sound wave module and vibrate in front and rear directions, the microneedle assembly having microneedles disposed at a front end; and a needle tip coupled to the front end of the microneedle assembly and having through-holes through which the microneedles selectively pass through formed corresponding to the microneedles.