Trauma surgical simulation: discussing the replacement of live animals used as human patient simulators.

BACKGROUND: Despite advances in simulator technology, live anaesthetised animals continue to be used as human patient simulators for medical professionals to practice techniques in the management of surgical trauma. This article describes the process of convening a working group of individuals with a professional interest in simulation to discuss the use of live animals and consider if and how they can be replaced in the future. MAIN BODY: A working group was formed of voluntary attendees to a workshop held at the SESAM 2023 conference. Iterative discussions reflecting on the topic were used to produce statements summarising the working group's opinions. The working group determined that live animals are used as human patient simulators due to the presence of accurate and responsive physiology in the presence of bleeding, realistic tissue tactility and an emotional response experienced by the learner due to interaction with the animal. They were unable to reach a consensus on replacement, determining that there is currently no single model which is able to provide all the learning aspects which a live animal model can provide. Several suggestions were made regarding development of technologies and pedagogical change. CONCLUSION: Replacement of live animals in surgical simulation is not straightforward but should be an aspiration, if possible. For the ongoing development of trauma surgical simulation models, it is important to combine the knowledge, skills and perspectives of medical stakeholders and educators, academic researchers and industry experts in producing alternative options to the use of live animal simulators.

Step-by-step development and evaluation of a 3D printed home-made low-cost pediatric tracheobronchial tree for foreign body aspiration extractions.

OBJECTIVES: The management of foreign body aspirations (FBA) is dreaded by pediatric physicians due to the high risk of respiratory distress and a potential fatal outcome, favored by a lack of experience of young specialists. Furthermore, there has been an increasing requirement for low-cost simulation. The aim was to describe the step-by-step manufacturing process and to validate a low-cost, easily home-made training model of pediatric tracheo-bronchial tree (pTBT) for simulation-based training in order to teach young physicians to practice foreign body (FBA) extractions. METHODS: A simulator was designed in order to reproduce the physical and esthetic properties of a pTBT. The production cost of a single simulator was estimated. The simulator was then tested by experienced physicians using a rigid bronchoscope. A manufacturing manual of the simulator is hereby presented. A group of 7 experienced pediatric otolaryngologists performed a FBA extraction in the conditions of installation of an operating room. RESULTS: The result of the survey showed a high fidelity of the simulator in mimicking the biological esthetics and physical properties of a pTBT during a FBA extraction (mean 4.3 ± 0.8). The total cost of the custom-made simulator is about 20.5 € ($23.4) for the production of the first simulator. CONCLUSIONS: A highly realistic and easily reproducible pediatric tracheo-bronchial tree simulator is presented and can therefore be used during simulation-based training.

Realization of Open Software Chain for 3D Modeling and Printing of Organs in Simulation Centers: Example of Renal Pelvis Reconstruction.

OBJECTIVE: Three-dimensional (3D) printing has many uses in healthcare such as in surgical training. It is becoming an interesting tool finding new pedagogical purposes in medical simulation. In this study, using a process consisting of 3D modeling, a simulator dedicated to pyeloplasty was designed, manufactured, and evaluated by experts. DESIGN: With the aid of open-source software and computer-aided design software, 3D models of a renal parenchyma, a renal pelvis and a ureter were created. This renal apparatus was processed and crafted with additive manufacturing using soft polymer materials. Polyvinyl alcohol material was used to print the components in order to make them dissectible and to evaluate their use in surgical teaching. SETTING AND PARTICIPANTS: Seven expert surgeons evaluated the model by performing a pyeloplasty sequence established in a previous work. An evaluation grid with 8 items related to surgical movement was rated on a 5-point Likert scale to assess how similar working with the model was to actual surgery. RESULTS: Three items were rated with a score greater than or equal to 4 (Needle penetration, Thread-sliding, and Cutting Strength). Suture strength was rated with a score above 3.5 for both renal pelvis and ureter, whereas elasticity was rated below 3. Handling and mobility properties were rated above 3 for the renal pelvis and below 3 for the ureter. The cost of the unit was $0.30 per renal unit. The primary difference identified was a difference in elongation between polyvinyl alcohol material and real biological tissue. CONCLUSIONS: It is feasible to generate and print a low cost upper urinary tract model from patient data imagery using environmentally friendly products that can be used effectively in surgical training. The simulator has been able to reproduce sensations related to surgical movements for a low cost. Hereafter, research into the pedagogical benefits provided to students, and through them, patients, should be performed. 3D printing models can offer new opportunities for healthcare simulation specific to different surgical fields.

3D-printed protected face shields for health care workers in Covid-19 pandemic.

The coronavirus pandemic resulted in a shortage of protective equipment. To meet the request of eye-protecting devices, an interdisciplinary consortium involving practitioners, researchers, engineers and technicians developed and manufactured thousands of inexpensive 3D-printed face shields, inside hospital setting. This action leads to the concept of "concurrent, agile, and rapid engineering".

Simulation and professional development: added value of 3D modelization in reproductive endocrinology and infertility and assisted reproductive technologies teamwork.

As in other specialties of medicine, there is more to clinical performance in reproductive endocrinology, infertility, and assisted reproductive technologies (REI-ART) than simply the individual knowledge and technical skills. Simulation is commonly used during fellowship training in REI-ART, aiming to produce a virtual cycle of professional development in order to improve patient outcome. With scientific certification and the joint development of evaluation tools, the contribution of digitalization, such as 3 D printing and digital simulators, will facilitate teamwork in REI-ART and enable a better transmission of knowledge in the specialty.