ABSTRACT
Introduction: Over the past decade, there have been outbreaks associated with high consequence infectious diseases such as Ebola virus disease, Lassa fever, and Monkeypox. The proper handling of clinical waste from patients infected with such pathogens is critical to ensure healthcare personnel and community safety. Methods: Mock clinical waste bags were created to simulate four distinct waste streams: personal protective equipment (PPE), dry linens, wet linens, and solidified liquids. Pressure and temperature data loggers were buried in the middle of simulated waste loads to record time at a sterilization temperature of 132°C (270°F) to reduce sterilization time. We also validated super rapid biological indicators (BIs) by embedding standard BIs (48 h), rapid BIs (3 h), and super rapid BIs (24 min) within each load. Cycles were validated over a 2-day period, using a total of 36 simulated waste bags (6 bags each for PPE, dry linen, and wet linen, and 18 bags for solidified liquids). Results: All waste bags achieved the target sterilization temperature, all BIs passed and cycle times were substantially decreased. For PPE waste processing, an estimated 15 h was saved for a 24-h period. Discussion: Default factory settings are inadequate to disinfect Category A clinical waste. Reliance on autoclave temperature readings may overestimate time at goal sterilization temperature for actual waste loads. Conclusions: The data provided by within bag data loggers and BIs allow for the optimization of autoclave parameters to increase throughput and enhance staff safety.
ABSTRACT
Temperature or relative humidity variations that fall outside the recommended parameters for the perioperative environment can have serious implications for patient safety and satisfaction as well as business continuity. Some pathogenic microbes can thrive in prolonged elevated humidity. Supplies and equipment in perioperative environments exposed to variations in temperature and humidity may become sources of infection or undergo alterations in function, putting patients at increased risk of harm. Other negative effects include increased costs, legal liability, and decreased patient satisfaction stemming from delays or rescheduled procedures. This article includes two hypothetical scenarios in which facility personnel respond to a condensation event and a fluid leak to avoid substantial negative effects in perioperative services. Also discussed is the role perioperative staff members play in preventing adverse consequences through rapid identification of temperature and humidity variations and early intervention. Finally, the existing guidelines on perioperative temperature and humidity and multidisciplinary risk assessments and recommendations for education, prevention, and risk mitigation are explored.
