Conference Session

Design in Biomedical Engineering (Works in Progress) - June 24th

Collection

2020 ASEE Virtual Annual Conference Content Access

Authors

Michael A. Phelan, Temple University; Aratrik Guha; Brandon K. Harrison, Temple University; George Moukarzel, Temple University; Abigail A. Tetteh; Yah-el Har-El, Temple University; Ruth Ochia P.E., Temple University

Tagged Divisions

Biomedical Engineering

, requires programs to evaluate students’ “ability to applyengineering design to produce solutions that meet specified needs…” (ABET EAC 2019-2020SO 2). This major design experience, typically a senior capstone project, should include theculmination of the foundational materials students learn during their course of study. ABET hasalso defined “engineering design” which includes many concepts of Design Thinking (DT). DTis a multistep process that begins with the formalization of the problem statement and movesthrough implementation of possible solutions with the needs of the end-user in mind. There areseveral ‘flavors’ of design thinking available and we have been following the 5-step designthinking process described by Plattner 2010 where the

Conference Session

Design in Biomedical Engineering (Works in Progress) - June 24th

Collection

2020 ASEE Virtual Annual Conference Content Access

Authors

Olga Imas, Milwaukee School of Engineering; Jeffrey A. LaMack, Milwaukee School of Engineering; Icaro Dos Santos, Milwaukee School of Engineering; Larry Fennigkoh P.E., Milwaukee School of Engineering; Charles S. Tritt, Milwaukee School of Engineering

Tagged Divisions

Biomedical Engineering

immersion and educationalexperiences that simulate a real-world industrial design process and encourage creativity,innovation and teamwork [2-5].In line with modern practices, our program’s design sequence focuses on system engineering,and includes key design phases of project definition, system-level design, prototypedevelopment, and verification and validation. In the most recent revision, we restructured ourdesign curriculum to ensure better continuity of design topics, to facilitate collaborative projectswith industry partners, and to alleviate various academic challenges noted by faculty andindicated by students in the course evaluation questionnaires. To this end, we reduced theduration of the capstone design sequence by three academic

Conference Session

Intro to Biomedical Engineering and Vertically Integrated Curriculum (Works in Progress) - June 23rd

Collection

2020 ASEE Virtual Annual Conference Content Access

Authors

Amber L. Doiron, University of Vermont; Jason H.T. Bates, University of Vermont; Ryan S. McGinnis, University of Vermont; Juan Jose Uriarte, University of Vermont; Niccolo M. Fiorentino, University of Vermont; Jeff Frolik, University of Vermont; Rachael A Oldinski

Tagged Divisions

Biomedical Engineering

BME capstone design course. BMECore 1 will comprise biomechanics, instrumentation, and sensors; BME Core 2 will comprisebiophysics, biomaterials, and transport; and BME Core 3 will comprise modeling biologicalsystems and signals. BME Design course 0 will provide the fundamentals of the design processand engage students with small team-based design projects motivated by the clinical needs ofcolleagues in our adjacent medical school. Design courses 1 and 2 will cover regulatorystandards and validation testing, respectively. BME Design 3 will consist of small-scale, team-based collaborations to aid in the transition into Capstone Design, which is required during the4th year. An elective second capstone semester will focus on commercialization of

Conference Session

Biomedical Engineering Curriculum and Design - June 24th

Collection

2020 ASEE Virtual Annual Conference Content Access

Authors

Steven Higbee, Indiana University Purdue University, Indianapolis; Sharon Miller, Indiana University Purdue University, Indianapolis

Tagged Divisions

Biomedical Engineering

Continually Challenged with Integrated Design ProjectsAbstractIntroduction: The undergraduate biomedical engineering (BME) curriculum should preparestudents to confidently approach complex problems, as graduates will enter the workforce in anenvironment of rising healthcare costs, decreasing average life expectancy, and significantsocioeconomic disparities in health outcomes. With this landscape, solutions to contemporaryproblems will require innovative thinking and groundbreaking medical technologies, suggestingthat the future of BME will be increasingly design-oriented. BME curricula generally includelaboratory and project components aimed at preparing students for senior capstone; however,students may begin capstone

Conference Session

Biomedical Engineering Curriculum and Design - June 24th

Collection

2020 ASEE Virtual Annual Conference Content Access

Authors

Kelsey Nicole Warren, Kansas State University; Charles Carlson, Kansas State University; Steve Warren, Kansas State University

Tagged Divisions

Biomedical Engineering

number of projects fall within the “sensors anddevices” area. Additionally, biomedical instrumentation has been an area of study for so long(e.g., when compared to a relatively new area such as tissue engineering) that a greater relativeweight in terms of the number of educational sensors and devices efforts is not surprising.Target students range in age from high school students (e.g., who attended summercourses/camps) up to seniors in college engaged in capstone design efforts. A large number ofpapers cited in the literature review were geared toward sophomore-to-senior-level students,whereas fewer were aimed at freshmen and high school students. This result may have beeninfluenced by the fact that many freshmen and high school courses attempt

Conference Session

Intro to Biomedical Engineering and Vertically Integrated Curriculum (Works in Progress) - June 23rd

Collection

2020 ASEE Virtual Annual Conference Content Access

Authors

Ross Aaron Petrella, University of North Carolina and North Carolina State University Joint Department of Biomedical Engineering; Lianne Cartee, University of North Carolina and North Carolina State University Joint Department of Biomedical Engineering; Devin K. Hubbard, University of North Carolina and North Carolina State University Joint Department of Biomedical Engineering; Kenneth Donnelly, University of North Carolina at Chapel Hill; David A. Zaharoff, University of North Carolina and North Carolina State University Joint Department of Biomedical Engineering; George T. Ligler, University of North Carolina and North Carolina State University Joint Department of Biomedical Engineering

Tagged Divisions

Biomedical Engineering

Design Curriculum. He holds a B.S. degree in Mathematics from Furman University and M.Sc. and D.Phil. degrees in Mathematics–Computation from the University of Oxford, where his studies were supported by a Rhodes Scholarship. c American Society for Engineering Education, 2020 Work in Progress: A Vertically Integrated Design Program Using Peer EducationIntroduction A yearlong capstone project for fourth year undergraduate biomedical engineering studentsis often put forward as the model for engaged, experiential learning [2, 3]. However, preparingstudents to undertake the breadth of such a project is often overlooked. In most undergraduateengineering curricula, there

Conference Session

Biomedical Engineers and Professional Development - June 23rd

Collection

2020 ASEE Virtual Annual Conference Content Access

Authors

Jeffrey A. LaMack, Milwaukee School of Engineering; Icaro dos Santos, Milwaukee School of Engineering; Larry Fennigkoh P.E., Milwaukee School of Engineering; Olga Imas, Milwaukee School of Engineering; Charles S. Tritt, Milwaukee School of Engineering

Tagged Divisions

Biomedical Engineering

of topics such as regulatory affairs [1] and engineeringstandards [2]. Although the combination of technical and “soft skills” can be an importantdistinguishing characteristic of biomedical engineers in industry, it is challenging to effectivelyteach students professional topics in an undergraduate biomedical engineering curriculum thatalso attempts to cover the breadth of engineering and life science topics that is the hallmark ofthe discipline.Recognizing the importance of professional topics, students are often required to implementthem in their culminating capstone design project. A common approach is to teach the topics inthe capstone design courses themselves, often by providing didactic sessions covering each topicjust before students

Conference Session

Design in Biomedical Engineering (Works in Progress) - June 24th

Collection

2020 ASEE Virtual Annual Conference Content Access

Authors

Collin W. Shale, Johns Hopkins University; Shababa Binte Matin, Johns Hopkins University; Nicholas J. Durr, Johns Hopkins University; Elizabeth A. Logsdon, Johns Hopkins University

Tagged Divisions

Biomedical Engineering

Paper ID #30608Inclusion of Industry Professional Experts in biomedical engineeringdesign courses at-scaleCollin W Shale, Johns Hopkins University Collin Shale is a junior lecturer with the Department of Biomedical Engineering at Johns Hopkins Uni- versity. Collin received his bachelor’s degree in biomedical engineering from Marquette University, and he received his master’s degree in bioengineering innovation and design from Johns Hopkins University, where he worked on projects relating to infection prevention for intravenous infusion and tuberculosis di- agnostics. Collin is an instructor for the capstone

Conference Session

Design in Biomedical Engineering (Works in Progress) - June 24th

Collection

2020 ASEE Virtual Annual Conference Content Access

Authors

Erica M. Comber, Carnegie Mellon University; Elisha Anthony Raeker-Jordan, Carnegie Mellon University; Kalliope Georgette Roberts, Carnegie Mellon University; Melanie Alexis Loppnow, Carnegie Mellon University; Andrew Hudson, Carnegie Mellon University; Wayne Chung, Carnegie Mellon University; Conrad M. Zapanta, Carnegie Mellon University

Tagged Divisions

Biomedical Engineering

addresses healthcare challenges and achieves the following:Objective 1: Leverages curriculum-acquired knowledge of both engineer and ID studentsObjective 2: Mimics the communication dynamic within the medical device industryMaterials and Methods: This year (2019-2020), the capstone course incorporated ID-centeredassignments on behalf of objective 1 and restructured project teams to consist of engineering andindustrial design subteams for objective 2. During the 2018-2019 and 2019-2020 academic years,4 and 6 industrial designers enrolled to work with ~50 BME students on 4 and 6 projectsrespectively. Engineering students’ team assignments both academic years were generated usingthe Comprehensive Assessment for Team-Member Effectiveness (CATME) system

Conference Session

Design in Biomedical Engineering (Works in Progress) - June 24th

Collection

2020 ASEE Virtual Annual Conference Content Access

Authors

Christopher Arena, Virginia Polytechnic Institute and State University; Elham Morshedzadeh, Virginia Polytechnic Institute and State University; John L. Robertson, Virginia Polytechnic Institute and State University; Andre Albert Muelenaer, Virginia Polytechnic Institute and State University; Brad D. Hendershot, DoD-VA Extremity Trauma and Amputation Center of Excellence, Walter Reed National Military Medical Center; Jessica L. O'Leary, Salem VA Medical Center; Aliza M. Lee, U.S. Department of Veterans Affairs; Devasmita Choudhury; Brandon C. Briggs; Pamela Jean VandeVord, Virginia Polytechnic Institute and State University

Tagged Divisions

Biomedical Engineering

academic partnerships between BME and ID. In 2006, a formalcollaboration was established between biomedical, electrical, mechanical, and computerengineering students from Marquette University (MU) and ID students from the MilwaukeeInstitute of Art and Design (MIAD) [3]. Mid-way through their one-year, multidisciplinary,capstone course, MU engineering students recruit MIAD students to further develop and refineconcepts. The MIAD students receive course credit and function as design consultants. Overall,the collaboration resulted in improved prototype functionality and aesthetics, and the studentsdeveloped an appreciation for each other’s discipline and role within the project team. There wasalso a desire among the students to work together from the

Conference Session

Laboratory Learning in Biomedical Engineering (Works in Progress) - June 24th

Collection

2020 ASEE Virtual Annual Conference Content Access

Authors

Scott Howard Seidman, University of Rochester

Tagged Divisions

Biomedical Engineering

need to learn embeddeddevelopment comes up repeatedly in the context of our capstone senior design experience, and hasresulted in the individual instruction of many students at our institution, over many years, often in theform of guided tutorials. While effective enough to support the capstone course, this approach does notexpose every student that wants to acquire this skill set with the opportunity to do so; such instruction islimited to those students that need to learn the skills to support a project. It also lacks the efficiency of aclassroom approach.Microcontroller skills can be acquired today without formal instruction. Students can learn much of thismaterial on their own through the “Maker Movement” [2], in which makers learn through

Conference Session

Biomedical Engineering Curriculum and Design - June 24th

Collection

2020 ASEE Virtual Annual Conference Content Access

Authors

Carolina Vivas-Valencia, Purdue University, West Lafayette; Nan Kong, Purdue University, West Lafayette; Eunhye Kim, Purdue University, West Lafayette; Senay Purzer, Purdue University, West Lafayette; Lindsey B. Payne, Purdue University, West Lafayette

Tagged Divisions

Biomedical Engineering

Engineering at Purdue Uni- versity. He received his PhD in Industrial Engineering from the University of Pittsburgh. His research interest includes big-data health analytics. He is actively in collaborating with international partners to enhance American engineering students’ global learning.Mrs. Eunhye Kim, Purdue University at West Lafayette Eunhye Kim is a Ph.D. student and research assistant in the School of Engineering Education at Purdue University. Her research interests lie in engineering design education, especially for engineering stu- dents’ entrepreneurial mindsets and multidisciplinary teamwork skills in design and innovation projects. She earned a B.S. in Electronics Engineering and an M.B.A. in South Korea

Conference Session

Laboratory Learning in Biomedical Engineering (Works in Progress) - June 24th

Collection

2020 ASEE Virtual Annual Conference Content Access

Authors

Sarah Corinne Rowlinson Furtney, University of Florida

Tagged Divisions

Biomedical Engineering

withbioinstrumentation, these courses constitute the dedicated teaching spaces (Figure 2) andfundamental skills that students use later in their course sequence in junior design and seniordesign. The University of Florida undergraduate biomedical engineering program is capped atone-hundred and twenty students for each graduating cohort, resulting in two sections of ~thirty-two students enrolled in the cellular engineering laboratory course each semester. A BFigure 2: The Cellular Engineering Laboratory has 8 Biological Safety Cabinets, with 4 shown in (A) andthe remaining mirrored behind, and a discussion space (B) where all students can see projected images.For the majority of students enrolled in Cellular Engineering Laboratory

Conference Session

Biomedical Engineers and Professional Development - June 23rd

Collection

2020 ASEE Virtual Annual Conference Content Access

Authors

Alexis Ortiz-Rosario, Ohio State University; Nathan Hyungsok Choe, Ohio State University; Amena Shermadou, Ohio State University; David A. Delaine, Ohio State University; Tanya M. Nocera, Ohio State University

Tagged Divisions

Biomedical Engineering

their senior capstone projects. His current projects include indus- try integration in the curriculum, undergraduate professional development, and entrepreneurial minded learning in the classroom.Dr. Nathan Hyungsok Choe, The Ohio State University Dr. Nathan (Hyungsok) Choe is a research assistant professor in department of engineering education at the Ohio State University. He obtained his PhD in STEM education at UT Austin. His research focuses on the development of engineering identity in graduate school and underrepresented group. Dr. Choe holds master’s and bachelor’s degrees in electrical engineering from Illinois Tech. He also worked as an engineer at LG electronics mobile communication company.Amena Shermadou