The present invention relates to methods for treating a microbial infection comprising administering a composition comprising one or more antibiotic compounds to the site of the infection by instilling the composition into the tympanostomy tube. A delivery cannula can be used to instill the composition into the tympanostomy tube.

A dilation catheter includes a shaft, a distal tip sized and configured to pass through an isthmus of a Eustachian tube (ET), and an expandable element moveable along an exterior of the shaft between a proximal position and a distal position. The expandable element is operable to transition between an unexpanded state in which the expandable element is configured for insertion into the ET via the isthmus, and an expanded state in which the expandable element is configured to dilate the ET.

An apparatus includes a rigid body, a flexible sealing element, a nozzle assembly, and an electrode. The rigid body defines a channel, a reservoir, and a vent path. The reservoir is in fluid communication with the channel. The vent path is in fluid communication with the reservoir. The reservoir is configured to provide spacing between the channel and the vent path. The sealing element is positioned distal to the rigid body. The nozzle assembly includes a nozzle head and a post. The post extends distally through the channel of the rigid body. The nozzle head projects distally from a distal end of the post. The electrode is disposed within the channel of the rigid body. The reservoir extends laterally from a longitudinal axis defined by the electrode.

A tympanostomy tube placement device has a needle with a tip, and a retainer at the needle tip. The retainer is within and retains by pulling radially inwardly a tympanostomy tube distal flange in a folded configuration extending distally. Movement of the needle tip in the proximal direction causes the adhesive bond to break and the distal flange releases to an unconstrained deployed position. Due to the axial folding of the distal flange its radial dimension does not affect deployment through the membrane.

A tympanostomy tube placement device has a stem with a needle having a tip configured to pierce a tympanic membrane. A retainer is on the needle and includes four fingers extending axially at a distance from said axis and at 90° circumferential separations in one example. The retainer is movable from a distal position at which it presses radially inwardly against the tube distal flange tabs to retain the distal flange in a folded position, to a proximal position at which the tube distal flange is free to spring out radially to a deployed position. The retainer fingers extend through tube proximal flange passageways and press the tube distal flange inwardly, while leaving a distally-facing face of the proximal flange exposed radially outwardly of the retainer. Hence, the proximal flange has its final deployed configuration throughout, and so can act as a physical stop member against the tympanic membrane and also provides visualisation for the surgeon because it extends radially outwardly of the stem.

This application relates to a stent inserted in an eustachian tube for treatment of eustachian tube dysfunction. In one aspect, the stent includes a pressure controller which blocks the eustachian tube and is opened/closed according to a pressure difference between front and rear portions thereof to control a pressure in the eustachian tube. The stent may also include a eustachian tube expansion portion which is connected to the pressure controller and has a hollow portion passed therein to make a fluid move in back and forth directions of the eustachian tube, and is inserted in the eustachian tube to expand the eustachian tube by transforming a shape thereof in a radial direction of the eustachian tube.

Provided is an otitis media treatment instrument and, more particularly, to an otitis media treatment instrument having a ventilation tube installed thereon, the otitis media treatment instrument including: a cutting sheath which is configured in a tube shape, and which has an inner diameter larger than the outer diameter of the ventilation tube; and a suction pipe formed to be able to move relative to the cutting sheath inside the cutting sheath along the longitudinal direction of the cutting sheath, the suction pipe having, on the front end portion thereof, an insertion portion having an outer diameter smaller than the inner diameter of the ventilation tube and having a fixing portion which extends toward the front end of the insertion portion, and which has an outer diameter larger than the inner diameter of the ventilation tube.

A method includes inserting into a patient body a medical suction tool, which includes a hollow first tube for removing material away from a Eustachian tube of a patient, and a hollow second tube disposed around the first tube. The medical suction tool is navigated to the Eustachian tube. The Eustachian tube is sealed by coupling an outer surface of the second tube to an inner surface of the Eustachian tube. While the Eustachian tube is sealed by the second tube, the material is removed away from the Eustachian tube via the first tube.

A therapeutic device (1) has a stem (3) having a distal end (60) configured for insertion in a patient's ear canal with latching by suction to the tympanic membrane so that there is no relative movement despite patient head movement. A needle (63) punctures the membrane after suction is applied by negative pressure via a lumen (66). The needle tip is located within a suction cup which grips the membrane. A hand-held control device (2) is coupled to the stem and has a user-actuated controller (8) for controlling application of negative pressure (7) to the suction lumen.

A fluidic bridging tube (1), for bridging membranes in the human or animal body allowing the passage of fluid, has a proximal flange (2), an inter lumen connector (3) with a lumen (5) and a distal flange (4). The tube comprises a metal skeleton or scaffold structure (51) and a surrounding polymer which is softer than the scaffold structure. The scaffold structure (51) has a tubular mesh providing structural strength to the inter lumen connector. The tubular mesh has members (61) defining substantial rectangular mesh apertures, and distal crowns (64). At its proximal end the scaffold structure comprises spines (68) extending from a proximal tubular mesh rim (63). The spines provide structural strength to the proximal flange (2). In the preferred embodiment the tube is a tympanostomy tube. A method of manufacturing the tube comprises providing the scaffold structure and over-moulding the outer material to form the shape of the proximal flange, the inter lumen connector with a lumen, and the distal flange.