The Internet, specifically the World Wide Web (WWW), has the potential to deliver science education materials directly to classrooms, media centers, libraries and homes. The current application seeks to use this new technology through a collaborative effort of an active scientist and a group of middle school science teachers to develop, disseminate and evaluate educational materials related to neuroscience for use in middle school science classes. This project attempts to introduce new technologies into the science classroom, extend science education to include the information superhighway and increase parental involvement in their children's education. Materials will be integrated with the existing middle school science curriculum and will include l) on-line and off-line experiments and activities covering a range of topics in neuroscience, 2) a "virtal neuroscience laboratory", 3) an Internet neuroscience resource list and 4) a "Neuroscientist Network" consisting of active neuroscientists around the world who will serve as experts answering student questions. All activities will be designed will attention to being self-paced, hands-on, entertaining and to involve Cooperative learning. Both quantitative and qualitative methods will be used to evaluate the usage of the Intemet Neuroscience Resource. It is hoped that this project will serve as a model to other scientists and teachers and to encourage them to develop Internet resources in their own areas of expertise for use in the classroom.
This project will disseminate neuroscience materials to secondary school science teachers via a CD-ROM. These materials will be evaluated to 1) determine changes in student attitudes toward science; 2) to assess changes in student knowledge of neuroscience concepts and 3) to quantify how students and teachers are using the Internet Neuroscience Resource ("Neuroscience for Kids"). The Scientific Attitude Inventory-II will be used to evaluate middle school student attitudes toward science before and after exposure to the Neuroscience Resource. Pretesting and posttesting of middle school students will be performed to evaluate content knowledge of neuroscience-related concepts and principles. Questions that comprise the content evaluation inventory will be based on the guidelines and benchmarks established by the American Association for the Advancement of Science, the National Research Council, and the National Science Teachers Association. Prior to general distribution, pretests and posttests for both attitude and content knowledge will be evaluated for validity and reliability with pilot group of middle school students. An Internet version of the Neuroscience Resource will continue to be developed.
Children's Hospital Oakland Research Institute (CHORI), in collaboration with the Hall of Health, a hands-on health museum, proposes a two year, Phase II SEPA project entitled Health and Biomedical Science for a Diverse Community. The purpose of this project is to disseminate (1) "Your Genes and Your Choices," a unique, interactive exhibit on social and genetic factors in health, and (2) a 4th and 5th grade health and biomedical science curriculum. The exhibit and curriculum were developed during Phase I. "Your Genes and Your Choices, "which has eight interactive stations and has been piloted at the Hall of Health, is designed for small science museums and health education centers. It will travel to four venues nationwide during Phase II and remain available to other venues after the grant ends. The innovative, activity based curriculum consists of eight instructional units that introduce students to scientific concepts and investigation in the context of the study of diseases and health conditions that disproportionately affect minority populations. The topics are: Fourth Grade: Unit 1: Nutrition: Balance and Imbalance (Obesity); Unit 2. Traumatic Brain Injuries; Unit 3. Infectious Diseases and Immunity; Unit 4. Environmental Toxics: Poisoning Prevention. Fifth Grade: Unit 1. Nutrition: Diabetes; Unit 2. Asthma and Lung Disease; Unit 3. Heart Disease; and Unit 4. Sickle Cell Anemia and Genetics. Each unit consists of five one hour lessons. The curriculum was piloted during Phase I, both in the classroom and in an after school science club, at two elementary schools serving predominantly minority children in Oakland, California. Now we propose to: (1) disseminate the curriculum via science clubs to ten elementary schools in Oakland and Berkeley; (2) offer a series of educator workshops to enhance the skills of teachers and after school personnel to teach scientific investigation and to incorporate the latest findings in biomedical science across the curriculum; and 3) hold family science festivals at each participating school to introduce parents to the topics of the science clubs. The festivals will include hands-on activities, talks by CHORI researchers, and focused discussions with healthcare providers on issues relating to minority health. This project involves clinical as well as basic science investigators, healthcare providers, teachers and health educators, high school and college students, and faculty from San Francisco State University and the University of California at Berkeley. The ultimate goals are to make science interesting and relevant to children who come from ethnically diverse, low income environments; to help them meet state and national objectives for learning in health, science, and scientific inquiry; to help them and their parents understand the relationship between science and health; and to foster their interest in science, so that they may consider future careers related to biomedical science. All project activities will be assessed through formative and summative evaluation. The science clubs will remain in place at the ten participating schools after Phase II funding ends, and the curriculum and evaluation tools will be posted on the internet, and thereby available to others.
Children's Hospital Oakland Research Institute (CHORI), in collaboration with the Hall of Health, a hands-on health museum, proposes a three-year Phase I SEPA project entitled "Health and Biomedical Science for a Diverse Community." The project entails development of a novel, interactive biomedical science curriculum for 4th and 5th grade students in low socioeconomic environments. Complementary to the curriculum, a hands-on exhibit on social and genetic factors in health will be developed to enhance learning by students and families. The curriculum and exhibit will be pilot tested with students from two elementary schools in Oakland, California. The curriculum--which will specifically address minority health issues such as asthma, obesity, diabetes, and heart disease--will include four five-lesson instructional units for 4th grade, and four five-lesson instructional units for 5th grade. In addition to classroom activities, the project will include workshops for teachers, family health and biomedical science nights, field trips to the Hall of Health, and an annual health and biomedical science festival for families. The project will involve clinical as well as basic science investigators, patients and families, and high school and college students. It will draw on the talents of teachers and health educators from the Oakland Unified School District, directors of SEPA projects at the Exploratorium in San Francisco and Lawrence Hall of Science in Berkeley, faculty at San Francisco State University and the University of California at Berkeley, and employees of LeapFrog, Inc., a company located in Emeryville, California, that makes interactive educational products. The ultimate goals of the project are to make science interesting and relevant to children who come from ethnically diverse, low socio-economic environments, to help them and their parents understand the relationship between science and health, and to foster their interest in science so that they may consider future opportunities in careers related to biomedical science. All project activities will undergo front-end, formative, and summative evaluation.
The Massachusetts Linking Experiences and Pathways Follow-on (M-LEAP2) is a three-year longitudinal empirical research study that is examining prospectively how early formal and informal STEM education experiences are related to gender-based differences in STEM achievement-related choices in middle and high school. M-LEAP2 serves as a complement to - and extension of - a prior NSF-funded study, M-LEAP, which was a largely quantitative research study that followed overlapping cohorts of 3rd - 6th grade female and male students for three years. M-LEAP surveyed over 1,600 students, 627 student-parent pairs, and 134 second parents in 8 diverse public schools across Massachusetts. In contrast, M-LEAP2 is a heavily qualitative three-year study using in-depth interviews with a diverse range of 72 of these students and their families to study how formal and informal science experiences shape the students' science-related beliefs, interests, and aspirations as they progress though middle and high school.
Researchers Jurow, Hall, and Ma examined how conversations and interactions between students and STEM professionals expanded students’ understanding of math modeling.
In this article Bell, Tzou, Bricker, and Baines describe how formal and informal educational experiences can merge through three case studies of youth engaged in science and technology. The theory of “cultural learning pathways” reframes our understanding of how, why, and where people learn over time and across spaces that have varying cultural values, everyday practices, and hierarchies of privilege and marginalization.
What is the relationship between experiences in informal settings and students’ understanding of and attitudes toward science? By analysing existing data sets, Suter finds that science museum attendance has an effect—albeit a small one—on student achievement.
The adoption of the Next Generation Science Standards means that many educators who adhere to model-based reasoning styles of science will have to adapt their programs and curricula. In addition, all practitioners will have to teach modeling, and model-based reasoning is a useful way to do so. This brief offers perspectives drawn from Lehrer and Schauble, two early theorists in model-based reasoning.
This literature review raises questions about how scientific argumentation is taught in schools. Manz argues that argumentation needs to be situated in real scientific questions and practices and makes suggestions for how to make argumentation an authentic science activity for students.
Researchers have described the inquiry process as involving five Es: engage, explore, explain, elaborate, and evaluate. Designed to facilitate the process of conceptual change in science, the 5E model can help students at almost any level engage in scientific practices. This brief correlates the 5E framework outlined by Bybee and colleagues with the science practices described in the Framework for K–12 Science Education.
This Barron and Bell article provides a foundational overview for how “cross-setting learning” can equitably engage all youth across formal and informal educational contexts. The paper offers: 1) a review of research; 2) descriptions of supports and challenges to cross-setting learning, including learner interest and identity; and 3) suggestions for research and assessments that capture learning for underrepresented youth.