A medical instrument includes an instrument shaft with exit holes near a distal end of the shaft, a tool coupled to the distal end of the shaft, and a backend. The backend may include a mechanism that manipulates a drive element that extends through the shaft and couples to the tool, a fluid inlet, and a fluid channel assembly providing fluid communication between the fluid inlet and the proximal end of the shaft. Cleaning fluid is directed into the fluid inlet, through the fluid channel assembly, and into the shaft. A chassis or other structural piece of the backend may form part of the fluid channel assembly.

The present disclosure relates to a light guiding assembly for light exposure of the interior of medical tubes, e.g. for disinfecting said tubes using ultraviolet-C (UVC) light. The light guiding assembly preferably comprises a coupling element, which in the proximal end is connectable to a light source assembly and in the distal end is connectable to a light guiding element. Said light guiding element preferably comprises a liquid filled polymer tube, a distal closure at the distal end of said tube, and a proximal closure comprising a gasket with overflow functionality at the proximal end of said tube. The present disclosure further relates to a method for filling said light guiding assembly.

The disclosure provides a cleaning brush configured to clean a working channel of the endoscope. The cleaning brush comprises a first joint, a second joint and a plurality of cleaning units, the plurality of cleaning units are sequentially connected, each cleaning unit comprises a cleaning portion configured to be in contact with the working channel of the endoscope, and the hardness of the cleaning portions of at least two cleaning units in the plurality of cleaning units is different. The first joint and the second joint are respectively connected with two outermost cleaning units in the plurality of cleaning units, and the first joint and the second joint are configured to be connected to make a ring-shaped cleaning brush. The cleaning brush is efficient in removing bioburden from the working channel of an endoscope.

The disclosure provides a cleaning brush configured to clean a working channel of the endoscope. The cleaning brush comprises a first joint, a second joint and a plurality of cleaning units, the plurality of cleaning units are sequentially connected, each cleaning unit comprises a cleaning portion configured to be in contact with the working channel of the endoscope, and the hardness of the cleaning portions of at least two cleaning units in the plurality of cleaning units is different. The first joint and the second joint are respectively connected with two outermost cleaning units in the plurality of cleaning units, and the first joint and the second joint are configured to be connected to make a ring-shaped cleaning brush. The cleaning brush is efficient in removing bioburden from the working channel of an endoscope.

Embodiments of the invention are directed to apparatuses and methods for cleaning and disinfecting probes. A cleaner is utilized to remove foreign materials (e.g., bioburden, soil, and other like material) from the probe after it is removed from the patient by soaking and/or flushing the foreign materials from the probe. The cleaner may be an enzymatic detergent that has bacteriostatic properties to inhibit bacterial growth within the apparatus. The multiple enzymes in the cleaner attack the foreign material, and include low-foam properties for effective recirculation across cycles within the cleaning step. The probe is rinsed after the cleaning step, and after rinsing a disinfectant process is applied to the probe. The disinfectant soaks and/or flushes the probe for a specified amount of time across cycles of recirculation to disinfect the surface of the probe, and afterwards the probe is rinsed thoroughly to remove the disinfectant from the probe.

Embodiments of the invention are directed to apparatuses and methods for cleaning and disinfecting probes. A cleaner is utilized to remove foreign materials (e.g., bioburden, soil, and other like material) from the probe after it is removed from the patient by soaking and/or flushing the foreign materials from the probe. The cleaner may be an enzymatic detergent that has bacteriostatic properties to inhibit bacterial growth within the apparatus. The multiple enzymes in the cleaner attack the foreign material, and include low-foam properties for effective recirculation across cycles within the cleaning step. The probe is rinsed after the cleaning step, and after rinsing a disinfectant process is applied to the probe. The disinfectant soaks and/or flushes the probe for a specified amount of time across cycles of recirculation to disinfect the surface of the probe, and afterwards the probe is rinsed thoroughly to remove the disinfectant from the probe.

An arthroscopic shaver cleaning device and method of cleaning an arthroscopic shaver blade/burr are disclosed. The arthroscopic shaver cleaning device includes a sleeve portion configured to interface with a proximal portion of a blade/burr of an arthroscopic shaver. The arthroscopic shaver cleaning device further includes a fluid connection portion having a fluid passageway configured to direct fluid toward the proximal portion of the blade/burr in order to dislodge debris entrapped in shaver lumen of the blade/burr.

An arthroscopic shaver cleaning device and method of cleaning an arthroscopic shaver blade/burr are disclosed. The arthroscopic shaver cleaning device includes a sleeve portion configured to interface with a proximal portion of a blade/burr of an arthroscopic shaver. The arthroscopic shaver cleaning device further includes a fluid connection portion having a fluid passageway configured to direct fluid toward the proximal portion of the blade/burr in order to dislodge debris entrapped in shaver lumen of the blade/burr.

A recirculating warm air system configured to connect to an air inflatable product is provided. The system includes a first chamber and a second chamber. The first chamber includes a first air inlet and a first valve located at the first air inlet. The second chamber includes a second valve located between the first chamber and the second chamber, an air outlet, and a first hose connected to the air outlet. The second chamber further includes an air blower and a heater located between the air blower and the air outlet. The second chamber includes a second air inlet, a third valve located at the second air inlet, and a second hose connected to the second air inlet. The first hose and the second hose are configured to connect to the air inflatable product. The system further includes a processing unit configured to control elements of the system.

The present disclosure relates generally to the field of medical devices and medical device accessories. In particular, the present disclosure relates to a tool or accessory for cleaning a medical device. For example, the tool or accessory may clean a fluid delivery lumen of an endoscopic submucosal dissection (ESD) knife. The tool or accessory may include a housing with a first portion of an elongate member secured within a first portion of the housing and a second portion of the elongate member extending into a chamber of the housing.