By Michele A. Korb and Umesh Thakkar
On a Monday morning in Pittsburgh, Pennsylvania, 29 sixth-grade students and their teacher conducted scientific investigations on insect adaptations by remotely controlling an environmental scanning electron microscope from their classroom. Before the session, these students gathered and mailed insect specimens to the Beckman Institute of the University of Illinois at Urbana-Champaign, where the electron microscope is physically located. Like any principal investigator, their teacher submitted a formal proposal to request access to the microscope for a classroom project (1). The proposal was to participate in the Beckman Institute's Bugscope, http://bugscope.beckman.illinois.edu, a free educational technology outreach project, which enables kindergarten to 12th grade (K-12) and undergraduate students and teachers to remotely access and control the microscope in real time from their classroom computers. For the teacher, the educational benefits to her students included the ability to see insect anatomy details too minute for their classroom microscopes; the development of the skills necessary to acquire their own images; and, most important, the opportunity to chat with scientists and ask them questions about insects, electron microscopy, and science careers.
There is growing interest in providing learning opportunities via the cyberinfrastructure (2). A National Science Foundation (NSF) report defined “cyberlearning” as “learning that is mediated by network computing and communication technologies” [p. 10 in (3)]. The report also suggested that, for students and teachers to learn how to author, publish, and curate data, they must acquire the skills of data scientists (see the first figure).
Bugscope hosted its first session in March 1999 (4). Since then, there have been 580 classroom sessions with 415 schools (106 of those being repeat participants) during which students and teachers have acquired 120,000 images (5). These sessions represent classrooms across K-12 grades and also occur in informal settings, such as libraries and museums, and in institutions of higher education.
Teachers and their students are responsible for planning their own scientific investigations to make the most efficient use of the time that they have been allocated on the microscope. Like professional scientists in different fields, they have an infrastructure of resident experts, such as the microscopist or an entomologist, to assist them in their investigations.
A standard classroom light microscope allows a magnification of around 1000×. Bugscope, which permits high-resolution imaging at over 20,000×, presents a unique opportunity for classrooms to collect data while discovering and understanding insects. For example, second-grade students from Milwaukee, Wisconsin, after seeing their specimens at a magnification of up to 10,000×, had the chance to “broaden their exposure to deeper understanding of the structures insects possess and perhaps widen their basic understanding of the microscopic world” [p. 31 in (6)] (see the second figure).
A recent report outlines a goal to prepare 100,000 trained middle and high school science, technology, engineering, and mathematics teachers by 2020 (7). Rather than just delivering content, undergraduate educators are being urged to address ways in which students and future teachers are prepared to gather and interpret scientific evidence and participate in scientific discourse (8). Projects like Bugscope in teacher education programs have the potential to increase relevant and meaningful uses of technology in K-12 classrooms. For example, in a typical Bugscope session in a science methods class, preservice teachers bring their own specimens to class (duplicate specimens are mailed to Beckman), make a drawing of the insect, and write questions they have regarding it. Next, their instructor models the use of Bugscope and trains the preservice teachers to use the microscope themselves. Throughout training, the class communicates via chat with the Bugscope experts. These preservice teachers also compare their drawings to images they acquired via Bugscope. Finally, preservice teachers are asked to design ways in which this experience can be implemented in a K-12 classroom, to explain how it contributes to inquiry and content knowledge, and to discuss how to manage their own sessions.
Seven recent graduates from two teacher education programs have implemented Bugscope sessions into their curricula. Some used the Bugscope session to stimulate student inquiry skills, while others had students create accurate insect sculptures based on the images they collected. In some classrooms, they guided students to use content and information from the chat transcripts to incorporate proper terminology into their writing. These sessions occurred during the regular school year and in summer school classes aimed at urban youth (see the third figure).
Reflecting on their preservice teacher education courses, two educators summarized what is exciting, engaging, and unique about Bugscope:
“My students, who experience poverty, violence, and challenging living environments, had the opportunity to control a $600,000 environmental scanning electron microscope. They chatted directly with scientists …. Most students learn the functions of insects by looking at pictures or drawings in a textbook. However, my fifth graders observed their own once-living specimens.”
“The power of Bugscope to transform science education cannot be underestimated. At a time when science has become merely an addendum to Math and Language-Arts curriculum in most public schools, Bugscope provides a powerful and instantaneous revitalization to a dying art … that of personally engaging and connecting students to the wonders of scientific inquiry and exploration.”
In successful online learning environments, students learn from engagement in scientific processes by challenging what they know in order to add to their understanding of how the world works. Bugscope is a sustainable and scalable model for classrooms nationwide to conduct their own scientific investigations.
M. A. Korb completed her Ph.D. in science education at Marquette University, where she incorporated Bugscope into her preservice teacher courses. She is an assistant professor in the Department of Teacher Education at the California State University, East Bay, and is a coprincipal investigator on an NSF Math and Science Partnership grant award 0962804. U. Thakkar has directed education and outreach of Bugscope since the beginning. He is a senior research scientist in the Coordinated Science Laboratory at the University of Illinois and is serving as a AAAS Science and Technology Policy Fellow in Washington, D.C.