The present disclosure generally relates to systems and medical sponge for cleaning needleless connectors. A medical sponge can include a shaped foam configured to engage a portion of the needless connector and a disinfecting solution applied to the shaped foam. A system can include the medical sponge and a liquid-impermeable pouch in which the medical sponge is separately retained. The medical sponge can include highly-abrasive and highly-conforming foam material in place of wipes or other sponge products. The foam material may be an open-cell micro abrasive material such as melamine foam. The foam material may contain disinfecting solutions such as isopropyl alcohol, chlorhexidine gluconate, or povidone-iodine.

The present disclosure generally relates to systems and medical sponge for cleaning needleless connectors. A medical sponge can include a shaped foam configured to engage a portion of the needless connector and a disinfecting solution applied to the shaped foam. A system can include the medical sponge and a liquid-impermeable pouch in which the medical sponge is separately retained. The medical sponge can include highly-abrasive and highly-conforming foam material in place of wipes or other sponge products. The foam material may be an open-cell micro abrasive material such as melamine foam. The foam material may contain disinfecting solutions such as isopropyl alcohol, chlorhexidine gluconate, or povidone-iodine.

There is disclosed a system and methods for debriding soft tissue from bone using a high-pressure water debridement system. One embodiment includes a cylindrical sleeve bounded by endcaps and having a drainage port positioned for effluent drainage. A central shaft is configured to receive a bone segment and is disposed along a longitudinal center of the sleeve and rotatively coupled between the endcaps. At least one high-pressure water nozzle is disposed on each side of the sleeve, each of which is positioned to impact the bone segment with a high-pressure water stream. A rotational actuator is configured to rotate the central shaft and the bone segment relative to the sleeve and the water nozzles such that when the high-pressure water nozzles are operational, the high-pressure water streams debride the bone segment. Other embodiments are also disclosed.

There is disclosed a system and methods for debriding soft tissue from bone using a high-pressure water debridement system. One embodiment includes a cylindrical sleeve bounded by endcaps and having a drainage port positioned for effluent drainage. A central shaft is configured to receive a bone segment and is disposed along a longitudinal center of the sleeve and rotatively coupled between the endcaps. At least one high-pressure water nozzle is disposed on each side of the sleeve, each of which is positioned to impact the bone segment with a high-pressure water stream. A rotational actuator is configured to rotate the central shaft and the bone segment relative to the sleeve and the water nozzles such that when the high-pressure water nozzles are operational, the high-pressure water streams debride the bone segment. Other embodiments are also disclosed.

A robot system includes a robot including an arm disposed in a first space , an operator that receives an operation on a test instrument in a second space , and a controller that operates the test instrument by controlling the robot in response to the received operation.

A trocar (10) is provided which permits cleaning of a medical device herein. In aspects, the trocar (10) has a seal (50) at a distal portion of the trocar (10). In use, a medical device, such as a laparoscope (200), passes through the seal (50) at the distal portion of the trocar (10). To clean a lens (210) at the end of the laparoscope (200), a vacuum is applied to the interior of the trocar (10), the laparoscope (200) is partially withdrawn so that it is proximal to the seal (50), and liquids and/or gases are introduced into the trocar (10) to clean the lens (210) while the laparoscope (200) remains within the trocar (10).

A self-cleaning suction device has a user's suction end that self-sanitizes externally and internally before and after use, as well as self-sanitizes internally during use. A cover opens to reveal the user's suction end within a containment unit. As the cover opens, the suction end travels from a lower chamber, proceeds through a middle chamber of a sanitizing agent, and is presented for use. After suction is complete, the suction end retracts through an upper chamber with, a scraping feature that removes debris from the outer surface of the mouthpiece, and proceeds down through the middle chamber of a sanitizing agent and a scraping feature that removes debris and the sanitizing agent from the outer surface of the user's suction end. Upon the sealing closure of the cover, the upper and middle chambers are flushed with a sanitizing agent, which is suctioned away along with any collected debris. The user's suction end resides within a lower chamber and can be decontaminated by a UV-C light entering into the lower chamber and/or corresponding chambers. The suction device can also include a liquid-hydration delivery system.

A holding device for a sterile product, in particular for a sterile product container or a soft packaging, which device is provided to hold, during a preparation process, a medical product to be sterilised, and comprises communication means, and a part of the communication means is designed for a frequency range such that the part, when the sterile product is closed, supplies data in relation to the medical product to an environment of the sterile product. Also provided are a sterile product and a method for monitoring a sterile product cycle.

Systems, devices and methods to improve safety and efficiency in an operating room comprise providing a suture package that holds new suture needles and needle receptacles for storing used needles. The devices can be safely worn for the surgeon to self-dispense new suture needles in the near surgical field and to secure the used needles into a needle trap or a needle retainer located on his extremity, on his operative instruments or on the surgical drapes. The device may provide automated and/or simplified needle counting both during use and after removal from the surgical field. The device may be configured for ergonomic and efficient use so as to minimize the actions and motions of the surgeon to dispense and secure the needle.

Systems, devices and methods to improve safety and efficiency in an operating room comprise providing a suture package that holds new suture needles and needle receptacles for storing used needles. The devices can be safely worn for the surgeon to self-dispense new suture needles in the near surgical field and to secure the used needles into a needle trap or a needle retainer located on his extremity, on his operative instruments or on the surgical drapes. The device may provide automated and/or simplified needle counting both during use and after removal from the surgical field. The device may be configured for ergonomic and efficient use so as to minimize the actions and motions of the surgeon to dispense and secure the needle.