RESUMO
INTRODUCTION: As well as preventing nosocomial and healthcare-associated infections, a reliable and eco-friendly washer for medical equipment would also be safe for the global environment. The aim of this study was to evaluate the efficacy of a newly developed automatic washing system (Nano-washer) that uses electrolyzed water and ultrasonication without detergent for washing endoscopes. METHODS: Patients who underwent laparoscopic lobectomy or laparoscopic colectomy at Nagasaki University between 2018 and 2022 were included. A total of 60 cases of endoscope use were collected and classified according to endoscope washing method into the Nano-washer group (using no detergent) (n = 40) and the manual washing group (n = 20). Protein and bacterial residues were measured before and after washing, using absorbance spectrometry and 16S rRNA polymerase chain reaction. The effectiveness of protein and bacterial removal and endoscope surface damage after washing were compared under specular vision between the groups. RESULTS: Nano-washer did not use detergent unlike manual washing. There was no difference in demographic or clinical characteristics between the groups except for the presence of comorbidities in the lobectomy group (Nano-washer, 85%; manual washing, 40%, P = .031). Compared with the manual washing group, residual protein levels in the Nano-washer group were significantly reduced after washing (lobectomy, 0.956 mg/mL vs 0.016 mg/mL, P < .001; colectomy, 0.144 mg/mL vs 0.002 mg/mL, P = .008). Nano-washer group showed a significant reduction in bacteria between before and after lobectomy (9437 copies/cm2 vs 4612 copies/cm2 , P = .024). CONCLUSION: Nano-washer is a promising, effective, and eco-friendly automatic washing device that is safer and more efficient than manual washing.
Assuntos
Detergentes , Desinfecção , Humanos , Desinfecção/métodos , Estudos de Viabilidade , RNA Ribossômico 16S , Contaminação de Equipamentos/prevenção & controle , Endoscópios/microbiologiaRESUMO
Removal of pathogenic organisms from reprocessed surgical instruments is essential to prevent iatrogenic infections. Some bacteria can make persistent biofilms on medical devices. Contamination of non-disposable equipment with prions also represents a serious risk to surgical patients. Efficient disinfection of prions from endoscopes and other instruments such as high-resolution cameras remains problematic because these instruments do not tolerate aggressive chemical or heat treatments. Herein, we develop a new washing system that uses both the alkaline and acidic water produced by electrolysis. Electrolyzed acidic water, containing HCl and HOCl as active substances, has been reported to be an effective disinfectant. A 0.15% NaCl solution was electrolyzed and used immediately to wash bio-contaminated stainless steel model systems with alkaline water (pH 11.9) with sonication, and then with acidic water (pH 2.7) without sonication. Two bacterial species (Staphylococcus aureus and Pseudomonas aeruginosa) and a fungus (Candida albicans) were effectively removed or inactivated by the washing process. In addition, this process effectively removed or inactivated prions from the stainless steel surfaces. This washing system will be potentially useful for the disinfection of clinical devices such as neuroendoscopes because electrolyzed water is gentle to both patients and equipment and is environmentally sound.
Assuntos
Candida albicans , Desinfecção/métodos , Peróxido de Hidrogênio/química , Pseudomonas aeruginosa , Aço Inoxidável , Staphylococcus aureus , Concentração de Íons de Hidrogênio , Propriedades de SuperfícieRESUMO
INTRODUCTION: Traditionally, laparoscopy has been based on 2-D imaging, which represents a considerable challenge. As a result, 3-D visualization technology has been proposed as a way to better facilitate laparoscopy. We compared the latest 3-D systems with high-end 2-D monitors to validate the usefulness of new systems for endoscopic diagnoses and treatment in Thailand. METHODS: We compared the abilities of our high-definition 3-D endoscopy system with real-time compression communication system with a conventional high-definition (2-D) endoscopy system by asking health-care staff to complete tasks. Participants answered questionnaires and whether procedures were easier using our system or the 2-D endoscopy system. RESULTS: Participants were significantly faster at suture insertion with our system (34.44 ± 15.91 s) than with the 2-D system (52.56 ± 37.51 s) (P < 0.01). Most surgeons thought that the 3-D system was good in terms of contrast, brightness, perception of the anteroposterior position of the needle, needle grasping, inserting the needle as planned, and needle adjustment during laparoscopic surgery. Several surgeons highlighted the usefulness of exposing and clipping the bile duct and gallbladder artery, as well as dissection from the liver bed during laparoscopic surgery. In an image-transfer experiment with RePure-L®, participants at Rajavithi Hospital could obtain reconstructed 3-D images that were non-inferior to conventional images from Chulalongkorn University Hospital (10 km away). CONCLUSION: These data suggest that our newly developed system could be of considerable benefit to the health-care system in Thailand. Transmission of moving endoscopic images from a center of excellence to a rural hospital could help in the diagnosis and treatment of various diseases.