Simulation as a tool to facilitate the healthcare organization adaptation to the COVID-19 pandemic

Introduction: During the COVID-19 pandemic professionals need to update the knowledge, attitudes and skills necessary to treat infected patients, and protect themselves against the transmission of the disease with limited medical supplies. The strategic use of a simulation center to facilitate the adaptation of a health service to the pandemic is described. Methods: The experience of a simulation center in Cantabria, Spain is analyzed. A working group identifies and classifies organizational needs into three areas: 1) learning (categorized with a zone system to tailor the design and implementation of training to specific needs);2) innovation (related to healthcare practice and healthcare equipment);and 3) sanitary supplies (which can be manufactured with the 3D printers available in the simulation center for teaching materials). Results: Three types of simulation training activities are implemented: train the trainer workshops for protection against drop-contact transmission, simulations for protection against aerosol transmission and a framework for the analysis of real situations with patients. Diving masks for ventilatory assistance, techniques for ventilating two patients with one ventilator and prototype ventilators are analyzed. Facial protection masks, swabs and mask forks are printed. Conclusion: The strategic participation of a simulation center can promote and facilitate the adaptation of a health system to a COVID-19 pandemic. © 2020 Elsevier España, S.L.U.

Role of 3D printing in the protection of surgical and critical care professionals in the COVID-19 pandemic

Background and objective There is a shortage of supplies for the protection of professionals during the COVID-19 pandemic. 3D printing offers the possibility to compensate for the production of some of the equipment needed. The objective is to describe the role of 3D printing in a health service during the COVID-19 pandemic, with an emphasis on the process to develop a final product ready to be implemented in the clinical environment. Methods A working group was formed between the healthcare administration, clinicians and other public and private institutions in Cantabria, Spain coordinated by the Valdecilla Virtual Hospital. The process included receiving the printing proposals, learning about the printing resources in the region, selecting the devices, creating a team for each project, prototyping, evaluation and redesign, manufacturing, assembly and distribution. Results The following supplies are produced: 1) devices that help protect providers: face protection screens (2400 units), personalized accessories for photophores (20 units) and ear-protection forks for face-masks (1200 units);2) products related to the ventilation of infected patients: connectors for non-invasive ventilation systems;and 3) oral and nasopharyngeal swabs (7500 units) for the identification of coronavirus carriers with the aim of designing action protocols in clinical areas. Conclusions 3D printing is a valid resource for the production of protective material for professionals whose supply is reduced during a pandemic. Resumen Antecedentes y objetivo Durante la pandemia de COVID-19 se produce una reducción del material para la protección de los profesionales. La impresión 3D ofrece la posibilidad de compensar la escasez de algunos de los suministros. El objetivo es describir el papel de la impresión 3D en un servicio de salud durante la pandemia de COVID-19, con énfasis en proceso para desarrollar un producto final listo para ser implementado en el entorno clínico. Materiales y métodos Se formó un grupo de trabajo entre la administración sanitaria, clínicos y otras instituciones público-privadas de Cantabria coordinado en el Hospital virtual Valdecilla. El proceso incluyó la recepción de las propuestas de impresión, el conocimiento de los recursos de impresión en la región, la selección de los dispositivos, la creación de un equipo para cada proyecto, diseño de prototipos, evaluación y rediseño, fabricación montaje y distribución. Resultados Se producen 1) dispositivos que ayudan a prevenir el contagio de los profesionales: pantallas de protección facial (2.400 unidades), accesorios personalizados para fotóforos (20 unidades) y horquillas salvaorejas para mascarillas (1.200 unidades);2) productos relacionados con la ventilación de pacientes infectados: conectores de sistemas de ventilación no invasive entre tubuladura y mascarilla;y 3) hisopos oro y nasofaríngeos (7.500 unidades) para la identificación de portadoras del coronavirus con el objetivo de diseñar protocolos de actuación en las área clínicas. Conclusiones La impresión 3D es un recurso válido para la producción de material de protección de los profesionales cuyo suministro está reducido durante una pandemia.

Role of 3D printing for the protection of surgical and critical care professionals in the COVID-19 pandemic. / Papel de la impresión 3D para la protección de los profesionales del área quirúrgica y críticos en la pandemia de COVID-19.

BACKGROUND AND OBJECTIVE: There is a shortage of supplies for the protection of professionals during the COVID-19 pandemic. 3D printing offers the possibility to compensate for the production of some of the equipment needed. The objective is to describe the role of 3D printing in a health service during the COVID-19 pandemic, with an emphasis on the process to develop a final product ready to be implemented in the clinical environment. METHODS: A working group was formed between the healthcare administration, clinicians and other public and private institutions in Cantabria, Spain coordinated by the Valdecilla Virtual Hospital. The process included receiving the printing proposals, learning about the printing resources in the region, selecting the devices, creating a team for each project, prototyping, evaluation and redesign, manufacturing, assembly and distribution. RESULTS: The following supplies are produced: 1) devices that help protect providers: face protection screens (2,400 units), personalized accessories for photophores (20 units) and ear-protection forks for face-masks (1,200 units); 2) products related to the ventilation of infected patients: connectors for non-invasive ventilation systems; and 3) oral and nasopharyngeal swabs (7,500 units) for the identification of coronavirus carriers with the aim of designing action protocols in clinical areas. CONCLUSIONS: 3D printing is a valid resource for the production of protective material for professionals whose supply is reduced during a pandemic.