ABSTRACT
INTRODUCTION: Technology Enhanced Learning (TEL) can provide the tools to safely master minimally invasive surgery (MIS) skills in patient-free environments and receive immediate objective feedback without the constant presence of an instructor. However, TEL-based systems tend to work isolated from one another, focus on different skills, and fail to provide contents without a sound pedagogical background. OBJECTIVE: The objective of this descriptive study is to present in detail EASIER, an innovative TEL platform for surgical and interventional training, as well as the results of its validation. METHODS: EASIER provides a Learning Management System (LMS) for institutions and content creators that can connect and integrate TEL "external assets" (virtual reality simulators, augmented box trainers, augmented videos, etc.) addressing different skills. The platform integrates all skills under an Assessment Module that measures skills' progress in different courses. Finally, it provides content creators with a pedagogical model to scaffold contents while retaining flexibility to approach course design with different training philosophies in mind. Three courses were developed and hosted in the platform to validate it with end-users in terms of usability, performance, learning results in the courses and student self-perception on learning. RESULTS: In total 111 volunteers completed the validation. The study was limited due to the COVID-19 pandemic, which limited access to external assets (virtual reality simulators). Nevertheless, usability was rated with 73.1 in the System Usability Scale. Most positive aspects on performance were easiness to access the platform, easiness to change the configuration and not requiring additional plug-ins to use the platform. The platform was rated above average in the six scales of the User Experience Questionnaire. Overall, student results improved significantly across the three courses (p < 0.05). CONCLUSIONS: This study provides, within its limitations, evidence on the usefulness of the EASIER platform for distance learning of MIS skills. Results show the potential impact of the platform and are an encouraging boost for the future, especially in the aftermath of the COVID-19 pandemic.
Subject(s)
Education, Distance , Minimally Invasive Surgical Procedures , Humans , Clinical Competence , COVID-19 , Learning , Minimally Invasive Surgical Procedures/education , PandemicsABSTRACT
The European Union is earmarking more and more resources each cycle to support research, development and innovation, and the projects set up by the working groups are helping to develop innovative solutions to reflecting societal issues of today. Since 2014, the Department of Surgical Research and Techniques of the Cardiovascular Center at Semmelweis University has been participating in international consortia supported by the Erasmus+ programme, which aim to modernise the teaching methodology of surgical training and to integrate IT technology into the training of surgical residents at pan-European level. This paper briefly summarises the international projects in which the Department has been involved over the last 7 years.
ABSTRACT
Introduction: Adhesion formation is a complex series of events that results from cellular and molecular processes where, in contrast to the normal case, events that support adhesion genesis dominate over adhesion lysis. Tissue injury, haemorrhage, tissue desiccation and inflammatory processes, among others, play a role in its induction. Since the presence of adhesions can be associated with a number of negative complications, the primary aim is to prevent their development. There are several preventive targets for the process, but in many cases therapy is only provided immediately after the procedure. In this study, we present an experimental rat model of adhesion, where the aim is to understand the stabilization period of adhesion. All animals underwent the same surgical procedure, inducing tissue injury, minor haemorrhage and tissue desiccation, differing only in the timing of reoperations and sampling. On postoperative days 17, we assessed macroscopically and histopathologically the type of adhesions formed, the adhesive tissue, the stability of the adhesion. We found that stabilization was a process lasting several days, with unstable and moderately stable adhesions predominating by postoperative day 4. Knowing this allows to broaden the therapeutic window, targeting the most appropriate period in the early postoperative period, possibly combining treatments, to make adhesion prevention even more effective.
Subject(s)
Cell Adhesion , Focal Adhesions , Animals , Hemorrhage , Inflammation , RatsABSTRACT
Introduction: Not only atraumatic surgical technique, precise bleeding control, removal foreign materials from the abdomen, but also avoiding desiccation or mechanical damage of peritoneal surface at abdominal surgery mean today evidence based expectation. Peritoneum with its extensive surface and special histological structure represents an important factor in normal physiological processes, furthermore as "Guard of abdomen" it has an important role to localise inflammatory reactions, useful as dialysing surface and provides also possibility for hyperthermic abdominal chemotherapy in tumour treatment. Largest part of peritoneal sac covers small intestine and colon. To prevent postoperative complications it is necessary to avoid desiccation of intestinal tract at laparoscopic and at open procedures as well consequently "rehyration" is a routine recommendation today. Desiccation of intestinal tract results postoperative adhesions, furthermore damage of serosa will increase permeability of intestine wall and can result perforation. All the surgical recommendations suggest keeping intestine moist, whereas there are only a few real studies in surgical literature to support or to deny this theory. Our study reviews the pathophysiological and surgical respects of this situation and summarizes the results of latest researches of combined functions of peritoneum.
Subject(s)
Laparoscopy , Peritoneum , Humans , Postoperative ComplicationsABSTRACT
Hernia is a defect of the abdominal wall. Treatment is principally surgical mesh implantation. Non-degradable surgical meshes produce numerous complications and side-effects such as inflammatory response, mesh migration and chronic pain. In contrast, the biodegradable, poly (vinyl alcohol) (PVA) based polymers have excellent chemical, mechanical and biological properties and after their degradation no chronic pain can be expected. The toxicology of PVA solution and fibers was investigated with Human dermal fibroblast- Adult cell line. Implantation tests were observed on long-term contact (rat) and large animal (swine) models. To measure the adhesion formation, Diamond and Vandendael score were used. Macroscopical and histological responses were graded from the samples. In vitro examination showed that PVA solution and fibers are biocompatible for the cells. According to the implantation tests, all samples were integrated into the surrounding tissue, and there was no foreign body reaction. The average number of adhesions was found on the non-absorbable suture line. The biocompatibility of the PVA nanofiber mesh was demonstrated. It has a non-adhesive, non-toxic and good quality structure which has the potential to be an alternative solution for the part of the hernia mesh.
Subject(s)
Polyvinyl Alcohol , Surgical Mesh , Animals , Biocompatible Materials , Hernia , Polymers , Rats , Swine , Tissue AdhesionsABSTRACT
Mast cells have been shown to release extracellular vesicles (EVs) in vitro. However, EV-mediated mast cell communication in vivo remains unexplored. Primary mast cells from GFP-transgenic and wild type mice, were grown in the presence or absence of lipopolysaccharide (LPS), and the secreted EVs were separated from the conditioned media. Mast cell-derived EVs were next cultured with LPS-naïve mast cells, and the induction of TNF-α expression was monitored. In addition, primary mast cells were seeded in diffusion chambers that were implanted into the peritoneal cavities of mice. Diffusion chambers enabled the release of GFP+ mast cell-derived EVs in vivo into the peritoneal cavity. Peritoneal lavage cells were assessed for the uptake of GFP+ EVs and for TNF-α production. In vitro, LPS-stimulated mast cell-derived EVs were efficiently taken up by non-stimulated mast cells, and induced TNF-α expression in a TLR4, JNK and P38 MAPK dependent manner. In vivo, using implanted diffusion chambers, we confirmed the release and transmission of mast cell-derived EVs to other mast cells with subsequent induction of TNF-α expression. These data show an EV-mediated spreading of pro-inflammatory response between mast cells, and provide the first in vivo evidence for the biological role of mast cell-derived EVs.
