Implementation of Health Technology Assessment and Management Course in Undergraduate Program in Biomedical Engineering ITB.

The Undergraduate Program in Biomedical Engineering ITB, Indonesia, introduce the Health Technology Assessment and Management as an elective course in 2021. This course is implemented to support the World Health Assembly that urges the member states to establish national strategies in health technology assessment and management, particularly medical devices. Furthermore, it is designed to give biomedical engineering students a broader insight into their career opportunities. Therefore, this course is delivered by the practitioner and guided by the main lecturer. The course syllabus is developed from the WHO Medical Devices Technical Series and European Network for Health Technology Assessment. It tries to implement HTA Core Model for Rapid Relative Effectiveness Assessments. A questionnaire is used to measure the students' perception of the course implementation. Moreover, it is used to obtain the students' comments and feedback. The course that is delivered by the practitioner not only gives the course content but also the context. After attending the course, students have a broader insight into the career opportunities as biomedical engineers in Indonesia.

Las normas técnicas para la formación en ingeniería biomédica, tecnología y administración en salud / Technical standards for the training in biomedical engineering, health technology and health management

Introducción: Los documentos normativos establecen el estado del arte relacionado con determinado campo del conocimiento. Existe una gran cantidad de normas relacionadas con los servicios de salud y su gestión, cuya aplicación es relevante en este sector. Objetivo: Exponer la importancia de las normas técnicas en la formación de los profesionales en ingeniería biomédica, tecnología y administración en salud. Desarrollo: Diferentes aspectos relacionados con el desempeño y las funciones de los profesionales en ingeniería biomédica, tecnología de la salud y administración en salud están recogidos en normas técnicas internacionales y en otras de carácter nacional, que resultan pertinentes y de gran utilidad para su formación en el nivel de grado y el posgrado. Conclusiones: Las profesiones abordadas requieren emplear los documentos normativos relacionados con sus funciones para contribuir con la calidad de los servicios de salud; de ahí la pertinencia de su incorporación en los planes de estudio de estas carreras(AU)

Introduction: Normative documents establish the state of the art related to a certain field of knowledge. There is a large number of standards related to health services and their management, whose application is relevant in this sector. Objective: To show the importance of technical standards in the training of professionals from the fields of biomedical engineering, health technology and health management. Development: Different aspects related to the performance and functions of professionals from the fields of biomedical engineering, health technology and health management are gathered in international and other national technical standards, relevant and useful for their training at the undergraduate and postgraduate levels. Conclusions: The addressed professions require the use of normative documents related to their functions in order to contribute to the quality of health services, hence the relevance of their incorporation into the curriculums of these major(AU)

Updating the Biomedical Engineering Curriculum in Latin America: Moving from management and maintenance to Design and Development of Medical Devices.

Biomedical Engineering as an undergraduate degree in Latin America is not new. However, most programs have the objective to produce professionals dedicated to the management and maintenance of health care technology. We believe that there is an important area of opportunity in the education of engineers who are competent in the design and development of medical devices. Among the 100 programs in the region there could be a few which could stand out as providers of such professionals. This work proposes a curricular structure to fulfill these aims.

Curricular Advancement of Biomedical Engineering Undergraduate Design Projects Beyond 1 Year: A Pilot Study.

A year-long design project is a typical requirement for an undergraduate engineering degree. However, the abbreviated, two-semester format limits most projects from reaching appropriate maturity for obtaining intellectual property (IP) protection, external funding, and/or peer-reviewed publications. The traditional model may be associated with some dissatisfaction with the abrupt ending of the work, as projects are often just completing their initial proof-of-concept testing after 1 year. This study reports the results of a pilot experiment that allowed such design projects to extend through a second year. We investigated three different mechanisms for continuation: research credits, a second-year curricular course (Advanced Design Teams), and extracurricular support. Students in this program continued to engage with an advisory board of clinicians, engineers, and other professionals, many of whom had assisted with the project during the first year. We investigated whether continuing the projects in a curricular fashion may provide a better avenue for productivity than extracurricular mechanisms. Based on the results of this pilot study, our department has formalized a curriculum to support teams beyond the first year, in which continuing students from the first-year teams can apply to continue their projects for credit toward their degrees.

Using information literacy to teach medical entrepreneurship and health care economics.

OBJECTIVE: Entrepreneurship and innovative product design in health care requires expertise in finding and evaluating diverse types of information from a multitude of sources to accomplish a number of tasks, such as securing regulatory approval, developing a reimbursement strategy, and navigating intellectual property. The authors sought to determine whether an intensive, specialized information literacy training program that introduced undergraduate biomedical engineering students to these concepts would improve the quality of the students' design projects. We also sought to test whether information literacy training that included active learning exercises would offer increased benefits over training delivered via lectures and if this specialized information literacy training would increase the extent of students' information use. METHODS: A three-arm cohort study was conducted with a control group and two experimental groups. Mixed methods assessment, including a rubric and citation analysis, was used to evaluate program outcomes by examining authentic artifacts of student learning. RESULTS: Student design teams that received information literacy training on topics related to medical entrepreneurship and health care economics showed significantly improved performance on aspects of project performance relevant to health care economics over student design teams that did not receive this training. There were no significant differences between teams that engaged in active learning exercises and those that only received training via lectures. Also, there were no significant differences in citation patterns between student teams that did or did not receive specialized information literacy training. CONCLUSIONS: Information literacy training can be used as a method for introducing undergraduate health sciences students to the health care economics aspects of the medical entrepreneurship life cycle, including the US Food and Drug Administration regulatory environment, intellectual property, and medical billing and reimbursement structures.

An Approach to Integrating Health Disparities within Undergraduate Biomedical Engineering Education.

Health disparities are preventable differences in the incidence, prevalence and burden of disease among communities targeted by gender, geographic location, ethnicity and/or socio-economic status. While biomedical research has identified partial origin(s) of divergent burden and impact of disease, the innovation needed to eradicate health disparities in the United States requires unique engagement from biomedical engineers. Increasing awareness of the prevalence and consequences of health disparities is particularly attractive to today's undergraduates, who have undauntedly challenged paradigms believed to foster inequality. Here, the Department of Biomedical Engineering at The City College of New York (CCNY) has leveraged its historical mission of access-and-excellence to integrate the study of health disparities into undergraduate BME curricula. This article describes our novel approach in a multiyear study that: (i) Integrated health disparities modules at all levels of the required undergraduate BME curriculum; (ii) Developed opportunities to include impacts of health disparities into undergraduate BME research projects and mentored High School summer STEM training; and (iii) Established health disparities-based challenges as BME capstone design and/or independent entrepreneurship projects. Results illustrate the rising awareness of health disparities among the youngest BMEs-to-be, as well as abundant undergraduate desire to integrate health disparities within BME education and training.

Structure and Management of an Engineering Senior Design Course.

The design of products and processes is an important area in engineering. Students in engineering schools learn fundamental principles in their courses but often lack an opportunity to apply these methods to real-world problems until their senior year. This article describes important elements that should be incorporated into a senior capstone design course. It includes a description of the general principles used in engineering design and a discussion of why students often have difficulty with application and revert to trial and error methods. The structure of a properly designed capstone course is dissected and its individual components are evaluated. Major components include assessing resources, identifying projects, establishing teams, understanding requirements, developing conceptual designs, creating detailed designs, building prototypes, testing performance, and final presentations. In addition to the course design, team management and effective mentoring are critical to success. This article includes suggested guidelines and tips for effective design team leadership, attention to detail, investment of time, and managing project scope. Furthermore, the importance of understanding business culture, displaying professionalism, and considerations of different types of senior projects is discussed. Through a well-designed course and proper mentoring, students will learn to apply their engineering skills and gain basic business knowledge that will prepare them for entry-level positions in industry.

Problem-Based Learning in Biomechanics: Advantages, Challenges, and Implementation Strategies.

Problem-based learning (PBL) has been shown to be effective in biomedical engineering education, particularly in motivating student learning, increasing knowledge retention, and developing problem solving, communication, and teamwork skills. However, PBL adoption remains limited by real challenges in effective implementation. In this paper, we review the literature on advantages and challenges of PBL and present our own experiences. We also provide practical guidelines for implementing PBL, including two examples of PBL modules from biomechanics courses at two different institutions. Overall, we conclude that the benefits for both professors and students support the use of PBL in biomedical engineering education.

Clinical Immersion and Biomedical Engineering Design Education: "Engineering Grand Rounds".

Grand Rounds is a ritual of medical education and inpatient care comprised of presenting the medical problems and treatment of a patient to an audience of physicians, residents, and medical students. Traditionally, the patient would be in attendance for the presentation and would answer questions. Grand Rounds has evolved considerably over the years with most sessions being didactic-rarely having a patient present (although, in some instances, an actor will portray the patient). Other members of the team, such as nurses, nurse practitioners, and biomedical engineers, are not traditionally involved in the formal teaching process. In this study we examine the rapid ideation in a clinical setting to forge a system of cross talk between engineers and physicians as a steady state at the praxis of ideation and implementation.

Defining new aims for BME programs in Latin America: the case of UAM-Iztapalapa.

The need for upkeep and management of medical technology has fostered the creation of a large number of under graduate programs in the field of biomedical Engineering. In Latin America alone, there are over 85 programs dedicated to this. This contrasts with programs in other regions where most of the undergraduates continue on to pursue graduate degrees or work as research and development engineers in the biomedical industry. In this work we analyze the situation regarding curricular design in the 48 BME programs in Mexico and compare this to suggestions and classifications of programs according to needs and possibilities. We then focus on a particular institution, Universidad Autónoma Metropolitana and due to its characteristics and performance we propose that it should redefine its aims from the undergraduate program on, in order to not only generate research but also to provide a nurturing environment for a budding biomedical industry in Mexico.

An assessment strategy for proposals of engineering projects in the Bachelor of Biomedical Engineering Curriculum at Universidad Autónoma Metropolitana-Iztapalapa.

Since 1974, the Bachelor of Biomedical Engineering Program (BBME) is offered at Universidad Autónoma Metropolitana-Iztapalapa, in Mexico City. By design, it must be completed in four years (12 trimesters) and, in the latter three, the senior students work on a BME project, which is done by completing three modules: Project Seminar (PS), Project on BME I and Project on BME II. In the PS module, the student must find a problem of interest in the BME field and suggest a solution through the development of an Engineering Project Proposal (EPP). Currently, the module is being taught by two faculty members of the BBME, who instruct students on how to develop their EPPs and evaluate their progress by reviewing a number of EPPs during the trimester. This generates a huge workload for the module instructors, which makes it necessary to involve more faculty members trimester-to-trimester (i.e. every 12 weeks) and, therefore, to create a set of systematic guidelines that ease the evaluation process for new instructors. Hence, the purpose of this paper is to present an assessment strategy (in the form of an assessment matrix) for the PS module as well as some preliminary results after two trimesters of its implementation.

Critical assessment and outlook for the 50 biomedical engineering undergraduate programs in Mexico.

Biomedical Engineering (BME) has been taught in Mexico at the undergraduate level for over forty years. The rationale for the introduction of this profession was to help manage and maintain the growing technological infrastructure in the health care system during the seventies. Owing to this, it is not surprising that early versions of the BME curricula were oriented towards clinical engineering and medical instrumentation. In the last decade the number of programs has grown from three in the seventies and eighties to fifty at present. This work is the result of the analysis of the BME programs in all the institutions that offer this degree in Mexico. Three main issues were studied: the curricula, the sub-disciplines that were emphasized in the programs and the job market. Results have shown a striking resemblance in most of the programs, which are mostly dedicated to teaching aspects of medical instrumentation and clinical engineering. These results reflect an agreement with the requirements of the job market, but since most job offerings are for low-paying positions in sales, service and hospital maintenance, we question the wisdom of stressing these sub-specialties at research universities, where faculties and research labs offer a wide variety of options. An analysis of work at these centers shows that most of the results are publications, so the need to emphasize translational research and partnerships with industry are suggested.

Evaluation of FCS self and peer-assessment approach based on Cooperative and Engineering Design learning.

The Cooperative Learning in Engineering Design curriculum can be enhanced with structured and timely self and peer assessment teaching methodologies which can easily be applied to any Biomedical Engineering curriculum. A study was designed and implemented to evaluate the effectiveness of this structured and timely self and peer assessment on student team-based projects. In comparing the 'peer-blind' and 'face-to-face' Fair Contribution Scoring (FCS) methods, both had advantages and disadvantages. The 'peer-blind' self and peer assessment method would cause high discrepancy between self and team ratings. But the 'face-to-face' method on the other hand did not have the discrepancy issue and had actually proved to be a more accurate and effective, indicating team cohesiveness and good cooperative learning.