[ Back to EurekAlert! ] Public release date: 22-Nov-2004
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Contact: Robert Florida
florida@njit.edu
973-596-5203
New Jersey Institute of Technology

New Jersey Institute of Technology pioneers new way to teach engineers

In Professor Richard Foulds' freshman design class, students perform angioplasty on pasta, amniocentesis on jelly donuts and surgery on hot dogs.

Foulds, along with other professors at New Jersey Institute of Technology (NJIT), is pioneering a new way to educate engineers. Professors who use the method, called studio learning, demonstrate the fundamentals of engineering not by lecture and recitation but by active, hands-on, experiment-based learning.

"Our students love studio learning, which has caused enrollment in the biomedical department to mushroom," says Foulds, PhD, an associate professor of biomedical engineering who shepherded the studio method to NJIT. "You will never see students, in my studio classes, asleep in the back of the room. You'll see their faces lit up with curiosity, inquiry and an active desire to learn."

Foulds was so happy with the results of implementing the teaching method at NJIT that he, along with two colleagues, published a paper, "Integrated Biomedical Engineering Education Using Studio-Based Learning," in the August 2003 issue of IEEE Engineering in Medicine and Biology Magazine.

And those who benefit most from the new teaching method are the students.

"The studio method is a much more intriguing way to learn," said Dennis Den Hollander, a freshman majoring in biomedical engineering. "It is hands-on learning, and it shows you the process engineers go through when they're designing something. It's a much more active way to learn. You learn not because a professor tells you, or lectures you, about something. You learn because you find answers by trial and error, by experimenting."

Foulds received three grants to pursue the project. The Whitaker Foundation provided a $30,000 grant to plan the studio concept. The National Science Foundation provided a $100,000 grant to develop studio courses, including the robot surgery class. And the New Jersey Commission on Higher Education funded the purchase of high-tech biomedical equipment used in the two studios.

Studio learning is an alternative to the conventional way of education engineers: a long lecture, followed by a recitation, followed by a lab experiment, says Foulds. Instead, a professor using the studio method starts class with a mini-lecture that touches upon the assigned reading, followed by a studio exercise that is conducted during the class period. Students divide into teams to work on the exercises, which are more open-ended than traditional lab experiments. The professor and the teaching assistant stay with the students in the studio, offering coaching and mentoring. It was first used in architecture schools, Foulds notes, but he adapted and appropriated it for engineering.

One recent afternoon in Foulds' freshman design class, students worked happily in teams, building surgical robots. Foulds darted from team to team, coaching the students on their robots. The class was alive with the hum of vivid discussions. The mock surgeries, performed on the pasta and other edibles, teach students how to use technology to assist surgeons. The students must first design prototypes of robots that will perform certain tasks, such as reattach the tip of a hot dog, which simulates surgery on an amputated finger. They then build the robots using LEGO Mindstorm kits, which have about 1,000 pieces - with gears, levers, motors and sensors.

"Surgical robots will play a critical role in the future of medicine," Foulds says, "allowing surgeons to not only be more precise, but to routinely perform operations from remote locations."

Studio learning promotes interaction among students and professors. In contrast to traditional lectures, studio sessions allow professors to mentor or coach the students. Biomedical engineering is the most interdisciplinary of the engineering fields, since in four years biomed majors must master aspects not only of mechanical, electrical and chemical engineering, but also of physiology, biology and medicine.

"The studio classes are ideally suited for interdisciplinary learning," says Foulds, "since the experiments we give them force our students to draw upon many fields."

The studios, also, are equipped with sophisticated equipment. The two studios are wired for the Internet and multimedia equipment. They are furnished with ten PC-based lab stations that serve groups of students. The studios have the equipment used by biomedical engineers, including amplifiers, oscilloscopes, power supplies, function generators and multi-meters.

Oftentimes the studio classes are taught by two professors. Bruno Mantilla, a special lecturer of biomedical engineering, teaches the freshman design class with Foulds. Before coming to NJIT, Mantilla worked for 15 years as a neurosurgeon. He knows, from experience, how engineers can help doctors develop new medical technology; and he knows how to teach students those techniques.

"Children are naturally inquisitive, creative," says Mantilla. "They ask questions. They explore the world with their hands. Yet too often when they get older, and start school, they are told, 'Stop asking questions, stop touching and start learning,' But that attitude kills learning. In our studio classes we ask our students to be creative, to drop all their pre-conceived notions of what engineering is and to come up with new ideas. It's really about creativity, which college students naturally possess. It just needs to be tapped. That's what the studio method does."

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New Jersey Institute of Technology, the state's public technological research university, enrolls more than 8,200 students in bachelor's, master's and doctoral degrees in 100 degree programs offered by six colleges: Newark College of Engineering, New Jersey School of Architecture, College of Science and Liberal Arts, School of Management, Albert Dorman Honors College and College of Computing Sciences. NJIT is renowned for expertise in architecture, applied mathematics, wireless communications and networking, solar physics, advanced engineered particulate materials, nanotechnology, neural engineering and eLearning.


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