Sampling systems and methods for non-invasive sampling of inner-colonic microbiome and its potential derivatives are provided. The sampling systems may operate in fluid communication with a large intestine cleansing system and comprise an electromechanical sampling device configured to collect at least a part of large intestine contents drained by the cleansing system. The electromechanical sampling device may comprise a collection unit configured to collect at least one sample from the contents, and an electromechanical robotic unit configured to move the collection unit to and from a sampling position and to manipulate the collection unit into a respective casing, to deposit the sample(s). Sampling methods may comprise optically monitoring drained contents of the large intestine, characterizing the optically-monitored (and possibly spectrally analyzed) drained contents to determine sampling times, and sampling the drained contents according to the characterization.

A collector (1) for collecting a liquid resulting from a nasal wash, the collector (1) comprising a funnel-shaped body (10) which terminates in a duct (12) that extends between an inlet (14) and an outlet portion (16) provided with coupling members (160) pre-arranged for coupling in a fluid-tight manner with a test tube (162) through a respective mouth (164); the duct (12) having filtering members (20) for the liquid.

A collector (1) for liquids provided with a first funnel-shaped body (10) delimited at the top by an annular edge (12) and provided at the bottom with an outlet (11) for liquids and with coupling means (100) for removable collection members (102) of the liquids from the outlet (11); a first front wall (120) and a second rear wall (122) carried in a hydraulically sealed manner by the annular edge (12) between two sides (124) of the first body (10) and mutually facing one another; the second wall (122) being delimited at the top by a concave curved segment (1220) shaped for shape coupling, in use, with an anatomic facial portion arranged between a user’s top lip and nose.

An orifice irrigation device includes a tubular component having a distal end and a proximal end and at least one bore axially extending from the proximal end to the distal end, the bore terminating at a plurality of orifices which extend at an angle from the bore; one or more flared wings coaxially positioned with respect to the tubular component, the at least one flared wing having a rim at its distal end; and one or more open flushing channels defined by the one or more flared wings, the flushing channels being defined by the side edges of the one or more flared wings.

An assembly for nasal irrigation for the handheld irrigation of a user's nasal cavity comprising a housing with a refill chamber containing irrigating fluid, an applicator, an actuator for forcing irrigating fluid from the refill chamber through the applicator into the user's nasal cavity during operation, and a solution port for refilling the refill chamber. Some embodiments of the present invention may further comprise a system for nasal irrigation that includes the assembly for nasal irrigation or handheld irrigator, as well as a solution assembly structured for dispensing irrigating fluid to the handheld irrigator, a docking station for removably housing the handheld irrigator, a solution assembly and a refill control, including a check valve.

A trans-anal irrigation (TAI) device has a pump base unit, an irrigation fluid reservoir, a wireless electronic controller, fluid tubing, and a disposable rectal catheter in fluid communication with the tubing. The rectal catheter has a retention balloon and a waste control valve. The fluid tubing contains two or three separate lumens for irrigation fluid and retention balloon inflation/deflation and optionally for waste control valve actuation. None of the lumens ever communicates with any other lumen. A hydraulic control circuit has a pump that pumps in one direction only but, with suitable control valves, is able to pump water to and from the retention balloon and to and from an optional waste control valve. A water temperature sensor is mounted in the pump base unit at a thin-wall section. The temperature sensor sends a signal to a controller which provides an indication of whether the water temperature is suitable for use.

Kits, devices, systems and related methods for obtaining a nasopharyngeal sample utilize a rinsing fluid supply component and a collecting component, which may be used as separate modules or integrated with a housing to form a handheld unit that may be operated with a single hand. The dispensing component may include a flexible reservoir pump containing a supply of rinsing fluid, and a first nostril interface adapted to engage a first nostril of a patient and guide a stream of rinsing fluid into the patient's nasal cavity. The collecting component may include a collection container and a second nostril interface adapted to engage a second nostril of a patient and collect effluent. An absorbent shield may be arranged on the integrated unit to absorb stray fluid.

Methods of administering an enema to a patient utilizing a fecal management system are disclosed. Such methods may include providing the patient utilizing the fecal management system and providing an enema solution providing apparatus. The enema solution providing apparatus may include a bag containing enema solution, tubing, a tubing connector, and an adjustable clamp. The method may include clamping a catheter of the fecal management system between an irrigation port and an collection bag, engaging the tubing connector with the irrigation port, actuating the adjustable clamp to commence a flow from the bag containing enema solution into the patient through the catheter, completing the flow from the bag containing enema solution into the patient, disengaging the tubing connector from the irrigation port; and unclamping the catheter. Kits for providing an enema through a fecal management system and enema solution providing apparatuses are also disclosed.

A suction-based medical dressing assembly and method of dermal irrigation provides a flexible tube that is fluidly coupled to at least two bifurcated tube portions defined by a plurality of apertures. The tube has a proximal end opening for discharging ambient fluid. The length of the bifurcated tube portions is surrounded by an absorbent gauze material covered substantially with an occlusive sheet material, and having an adhesive strip thereon. A vacuum assembly creates a negative pressure in the tubes. The ambient fluid is absorbed by the absorbent material, and the negative pressure sucks the fluid through the apertures in the bifurcated tube portions for discharge through the opening in the tube. In operation, a patient applies the adhesive side of the occlusive device to the skin where liquid removal is desired and activates the vacuum-inducing source, thereby causing fluid runoff from the patient to be effectively removed for disposal.

An ear disimpactor for disimpacting material impacted in an ear canal and against a tympanic membrane, is disclosed. The impacted material comprises cerumen, insects, and other debris. The ear disimpactor comprises a housing, a warm water irrigation unit, and a suction unit. The housing comprises an ear speculum attached to an outer surface of the housing, a motorized auger comprising a drill bit extending from the motorized auger to a tip of the ear speculum, a warm water line extending from the tip of the ear speculum and across a length of the housing, and a suspension suction tube extending from the tip of the speculum and across the length of the housing. The warm water irrigation unit provides warm water to the ear canal through the warm water line and the suction unit sucks out suspension from the ear canal.