A Weed Cantilever

One dilemma science teachers face every day is balancing the content demands of state and federal testing requirements while providing opportunities for inquiry. Using the 5E learning cycle is a realistic, constructivist way to address this dilemma. The 5E learning cycle leads students through a sequence of learning in which they become engaged in a topic, explore that topic, are given an explanation for their experiences, elaborate on their learning, and are evaluated. This article outlines a 5E learning cycle introducing middle/high school students to the cell.     

Arduino-Assisted robotic and coding applications in science teaching: Pulsimeter activity in compliance with the 5E learning model

Abstract

The purpose of the current study is to design and develop an Arduino-assisted robotic and coding activity in compliance with the 5E learning model for middle school students to construct knowledge and realize learning in science teaching. The study was conducted on 6^th grade students attending a private middle school in Turkey in the second term of the 2018 and 2019 school year. Application of the designed activity was carried out in the science laboratory with the participation of 10 students who were the members of the STEM club. The activity was designed to teach the concept of pulse addressed within the subject of circulatory system in the science curriculum in line with the 5E learning model. With this activity developed, systematic contraction and relaxation movements of the heart while working were modeled through robotics and coding. In addition, through this activity, it was intended to introduce the students to coding, to improve their attitudes towards technology, to develop their information processing skills and to help them to relate the concept of pulse to daily life. In this way, the students were provided with opportunities to experience Arduino-assisted robotic and coding applications and to integrate such applications into their daily life.     

Science Classroom Inquiry (SCI) Simulations: A Novel Method to Scaffold Science Learning

Science education is progressively more focused on employing inquiry-based learning methods in the classroom and increasing scientific literacy among students. However, due to time and resource constraints, many classroom science activities and laboratory experiments focus on simple inquiry, with a step-by-step approach to reach predetermined outcomes. The science classroom inquiry (SCI) simulations were designed to give students real life, authentic science experiences within the confines of a typical classroom. The SCI simulations allow students to engage with a science problem in a meaningful, inquiry-based manner. Three discrete SCI simulations were created as website applications for use with middle school and high school students. For each simulation, students were tasked with solving a scientific problem through investigation and hypothesis testing. After completion of the simulation, 67% of students reported a change in how they perceived authentic science practices, specifically related to the complex and dynamic nature of scientific research and how scientists approach problems. Moreover, 80% of the students who did not report a change in how they viewed the practice of science indicated that the simulation confirmed or strengthened their prior understanding. Additionally, we found a statistically significant positive correlation between students’ self-reported changes in understanding of authentic science practices and the degree to which each simulation benefitted learning. Since SCI simulations were effective in promoting both student learning and student understanding of authentic science practices with both middle and high school students, we propose that SCI simulations are a valuable and versatile technology that can be used to educate and inspire a wide range of science students on the real-world complexities inherent in scientific study.     

Teacher candidates in the garden

Recent science education reform has led to an increased emphasis on engaging students in inquiry and science practices rather than having them simply memorize scientific facts. However, many teachers of elementary science may themselves have had more traditional science learning experiences, and may therefore be unsure about inquiry-based teaching methods. One way to enhance preservice teachers' comfort with and desire to teach science using a hands-on approach might be to engage them in science learning experiences alongside children during their educator preparation program. The purpose of this article is to share how one faculty member and a cooperating teacher from a partner school involve teacher candidates in working with children in the school's garden, allowing them to personally experience inquiry while witnessing firsthand the potential benefits to children of authentic science learning through garden based activities.     

Connecting ecology to daily life: how students and teachers relate food webs to the food they eat

This study used sociocultural learning theory to better understand how middle and high school environmental science and biology students and pre- and in-service science teachers connect the daily life activity of eating to the food web model learned in school. We sought to understand how student and teacher perceptions of the environment and their experiences influenced their responses to interview questions regarding this topic. Findings, based on transcribed interviews with 54 study participants, indicate that three quarters of teachers and students were unable to connect the food they eat with ecosystem food webs. Even so, many respondents particularly those from elite public schools, did not demonstrate common food web misconceptions identified by other researchers, instead showing a sophisticated understanding of food web interactions. These findings indicate that even though participants were proficient in their school science understanding of food web interactions, they did not readily think about how their everyday out of school activities, like eating, relate to those interactions. This may be representative of a more general disconnect between formal ecology instruction and daily life activities. We provide several recommendations for how this disconnect can be remedied in our classrooms.     

Race to the Future: Integrating 21st Century Skills into Science Instruction

Race to the Future is an exciting and dynamic activity modeled after the reality television show The Amazing Race. It exemplifies how 21st century skills can be incorporated into core subject instruction and at the same time positively enhance student engagement. In this activity, students work quickly and cooperatively with their teammates and use 21st century skills to successfully decipher five clues related to science content. We have used this activity with excellent results with different groups of students (middle school, high school, and university students), for different purposes (ice-breaker, team-building, course assessment, and evaluation), and in broad curriculum areas (science and math). However, the activity is especially powerful when introduced during the first day or week of class. The meaningful and enjoyable student collaboration, the upbeat class environment, and the enhanced student engagement achieved at the conclusion of this challenging activity set an optimal teaching and learning environment for the entire quarter/semester.     

Digital game design-based STEM activity: Biodiversity example

Abstract

The purpose of this study is to design a digital game design-based STEM activity for fifth-grade students learning about endangered organisms and significance of biodiversity for living. This activity was carried out with twenty students in a public school in Eastern Black Sea Region of Turkey during academic year of 2018–2019 spring term. This study planned as eight-lesson time (8?×?40?minutes) and completed at this lesson time. The students were given the digital game design challenge in real-life problem context that has been created based on design-based science learning and for which they shall use their knowledge and skills in each of the STEM disciplines. During this design challenge, students worked like a scientist and an engineer. They carried out scientific research and inquiry process in the science discipline, understood the engineering design process in the engineering discipline, established mathematical relations in the mathematics discipline, learned how to make coding in the technology discipline, and used this knowledge and skills thus acquired in their suggested solutions for the design challenge. They designed a digital game by coding and presented science knowledge and skills that acquired from inquiry process.     

All Aboard! The Polar Express Is Traveling to Science—Understanding the States of Matter while Differentiating Instruction for Young Learners

This standards-based science lesson introduces young learners to scientific inquiry and critical thinking by using activities to demonstrate three phases of matter (solid, liquid, and gas). By learning about the states of matter through a 5E instructional approach, students are encouraged to observe changes in the states of matter and to discuss their understanding in both small and large group forums. Student participants will be involved in hands-on activities along with small and large group discourse while actively learning about the states of matter and enjoying a hot chocolate demonstration with sampling. Developmentally appropriate instructional approaches are emphasized throughout this lesson.     

Size-dependent properties of matter: Is the size of a pill important?

This interdisciplinary scientific inquiry lesson specifically utilizes the 5E learning cycle to engage high school students in an investigation on size-dependent properties of matter. In particular, this inquiry lesson focuses on a biologically relevant phenomenon, namely accessibility to a pharmaceutical drug with respect to the size of the pill. In this context, students design and conduct a controlled experiment to test how the accessibility to an encapsulated drug is affected by the change in the size of the pill. Thus, through this investigation, students not only learn about the relationship between the size of a material in terms of surface area-to-volume ratio and the rate of diffusion of molecules, but also extend this knowledge to the importance of size in the context of nanoscale. Additionally, students practice the science process skills involved in undertaking a scientific inquiry.     

The Ups and Downs of Frogs

Vocabulary is the essential element of comprehending concepts in content areas. Many words used in science content-area materials are used to define concepts and to increase the conceptual development of the content area. Conceptual development is a major goal of content-area instruction. Without a clear understanding of the language of the science content, students will certainly experience difficulty and a lack of interest with their science content-area material. Providing students with inquiry strategic vocabulary strategies can significantly support their understanding and interest concerning the language of science. As a result of using engaged vocabulary strategies, teachers can help students bridge the gap between the language of the science content and the language and background knowledge that students bring to the class. This article is easily adaptable for grades 6-12, and it is applicable to all science areas. It provides the middle and high school science teacher with five engaged learning vocabulary strategies that will help students become active participants in the learning process as they master their content area material. In addition, the article offers a pre- and postevaluation Science Vocabulary Questionnaire.     

Local Tree Mapping: A Collaborative,Place-Based Activity Integrating Science,Technology, Math,and Geography

This inquiry-based activity designed for the fifth through 12th grade allows students to engage in an outdoor, place-based experience, working collaboratively both in groups and as a class to accomplish the class goal of creating a local tree map linked to student-collected data about each tree. During Local Tree Mapping, students explore the local trees in the yard or neighborhood of the school, while learning basic skills in geographical information systems and Microsoft Excel. Through this activity, students gain a deeper understanding of and appreciation for the role of trees within the Earth's ecosystems, as they collect data on tree type, height, diameter, age, and the longitude and latitude of the trees. An extension activity is described in which students can enter their tree data into a carbon dioxide (CO₂) emissions reduction calculator to determine how much CO₂ is sequestered by the trees in their research site. Local Tree Mapping provides an opportunity for students to gain inquiry skills in science, mathematics, and geography as they participate firsthand in the collection, analysis, and presentation of real-world data that can be utilized by the local community.     

Observing Rocks in the Elementary Grades…

The ocean is a major influence on weather and climate. With this set of lessons, middle school Earth systems science teachers can help their students build an understanding of how large bodies of water can serve as a heat source or sink at different times and how proximity to water moderates climate along the coast. The activity's combination of laboratory investigation, map study, and graphing applies different learning styles and provides practice in important science processes. The activities are adapted from Earth Systems Education Activities for Great Lakes Schools: Great Lakes Climate and Water Movement (V. J. Mayer et al. 1996).     

Patterns of Change: Forces and Motion

Patterns of Change: Forces and Motion is an integrated science lesson that uses the 5E lesson cycle to tie together science with language arts, mathematics, literature, technology, engineering and social studies in an engaging format applicable for young learners. This lesson has been uniquely designed for the purpose of providing elementary teachers with ideas for using hands-on minds-on activities to foster inquiry and discussion, while engaging their students to use technology as a learning tool. This lesson has been used on the elementary level to teach students about the forces that have an effect on motion.     

Backyard evolutionary biology: Investigating local flowers brings learning to life

Inquiry‐based learning allows students to actively engage in and appreciate the process of science. As college courses transition to online instruction in response to COVID‐19, incorporating inquiry‐based learning is all the more essential for student engagement. However, with the cancelation of in‐person laboratory courses, implementing inquiry can prove challenging for instructors. Here, I describe a case that exemplifies a strategy for inquiry‐based learning and can be adapted for use in various course modalities, from traditional face‐to‐face laboratory courses to asynchronous and synchronous online courses. I detail an assignment where students explore the developmental basis of morphological evolution. Flowers offer an excellent example to address this concept and are easy for students to access and describe. Students research local flowering plants, collect and dissect flower specimens to determine their whorl patterns, and generate hypotheses to explain the developmental genetic basis of the patterns identified. This task allows students to apply their scientific thinking skills, conduct guided exploration in nature, and connect their understanding of the developmental basis of evolutionary change to everyday life. Incorporating inquiry using readily available, tangible, tractable real‐world examples represents a pragmatic and effective model that can be applied in a variety of disciplines during and beyond COVID‐19.     

Kymographs,stimulators, and kymographs with stimulators

This biology investigation on Pristipomoides filamentosus larval development, survival, and aquaculture research was developed with three educational objectives: to provide high school students with (1) a scientific background on the biology and science of fisheries as well as overfishing, its consequences, and possible mitigations; (2) exposure to field and laboratory techniques in marine science; and (3) practical skills in scientific inquiry and investigation. We teach this investigation at the Hawai‘i Institute of Marine Biology, where we have access to captive broodstock of the pink snapper, P. filamentosus. During this investigation students follow several steps scientists take to study aquaculture: collecting spawn from outdoor fish pens, quantifying the number of eggs, determining the percentage of fertilisation, and estimating the time of spawning and hatching. Additionally, students perform hypothesis-driven science activities with the embryos to test the effects of water quality on their development and survival. In this paper we discuss background information of aquaculture, specifically of P. filamentosus, and thoroughly describe the several components of delivering the investigation. Lastly, we provide possible outcomes of students’ performances in the laboratory activities, and discuss how effectively the exercise met its educational objectives.     

Evolution and Medicine: An Inquiry-Based High School Curriculum Supplement

Evolution and Medicine is a curriculum supplement designed by the National Institutes of Health (NIH) and the Biological Sciences Curriculum Study (BSCS) for high school students. The supplement is freely available from NIH’s Office of Science Education (OSE) as a part of the NIH curriculum supplement series. Development of the supplement was a collaborative effort that included input from a panel of experts in medicine, evolution, education, and educational technology. In total, the curriculum supplement includes five inquiry-based lessons that are integrated into the BSCS 5E instructional model (based on constructivist learning theory). The goal was to develop a 2-week curriculum to help students understand major concepts of evolution using the dynamic, modern, and relevant context of medicine. A diverse group of students and teachers across the US participated in a formative evaluation of a field test version of the curriculum. High school students made significant learning gains from pretest to posttest, with a relatively large effect size for student understanding of common ancestry and a relatively small effect size for student understanding of natural selection. There was no statistically significant difference in achievement gains between white students and all other racial/ethnic categories. Overall, the evaluation suggests that a curriculum that emphasizes the role of evolution in medicine, uses a constructivist instructional model, and is grounded in inquiry is relatively well-received by teachers and students and shows promise for increasing student learning in evolution.     

Using Team-Based Learning to Teach Grade 7 Biology: Student satisfaction and improved performance

Team-based learning (TBL) is an innovative form of collaborative learning. The purpose of this study was to evaluate TBL’s effect on the performance and satisfaction of grade 7 students in biology in a private school in Lebanon, as well as teachers’ willingness to implement this new methodology. An exploratory study was performed whereby two biology units were taught to two groups of students using either TBL (60 students) or traditional lecture-based instruction (30 students). Later, a summative test was administered to evaluate students’ performance. Students’ attitudes were evaluated using a questionnaire and teachers’ classroom observations. Finally, science teachers’ willingness to try TBL in their classes was assessed using a questionnaire (14 teachers). Results showed that underachievers taught according to TBL did better than underachievers taught with the lecture-based approach. The majority of students enjoyed TBL and found it useful and fun. Finally, science teachers agreed that TBL is a good alternative to the traditional lecture-based method.     

Metacognitive inquiry activities for instructing the central dogma concept: ‘button code’ and ‘beaded bracelet making’

ABSTRACT

The central dogma of biology is difficult to learn because its microscopic processes cannot be visualized. This study aimed to devise two inquiry activities: ‘Button Code’ and ‘Beaded Bracelet Making,’ involving the concepts of DNA replication and protein synthesis based on the Metacognitive Learning Cycle (MLC) for students, and to explore the effectiveness of concept learning of the central dogma, how students’ metacognition may be expressed, and students’ perceptions of their inquiry performance. We developed a ‘Concept journal’ including metacognitive scaffolds, and employed the ‘Central Dogma Achievement Test’ as a tool for the above purpose. A total of 18 junior high school students participated in this inquiry course instructed by two of the authors. The results showed that students’ achievement performance was significantly improved on the whole, the students’ metacognition was expressed during the process of inquiry with scaffolding, and most students gave positive responses about their learning performance. According to the results, this inquiry course could develop students’ comprehension of the central dogma concept, and give students opportunities to practice metacognition that might lead to effective learning in inquiry activities. The implications and expandability of this course are discussed.     

Grass Gazers: Using citizen science as a tool to facilitate practical and online science learning for secondary school students during the COVID‐19 lockdown

The coronavirus disease of 2019 (COVID‐19) pandemic has impacted educational systems worldwide during 2020, including primary and secondary schooling. To enable students of a local secondary school in Brisbane, Queensland, to continue with their practical agricultural science learning and facilitate online learning, a “Grass Gazers” citizen science scoping project was designed and rapidly implemented as a collaboration between the school and a multidisciplinary university research group focused on pollen allergy. Here, we reflect on the process of developing and implementing this project from the perspective of the school and the university. A learning package including modules on pollen identification, tracking grass species, measuring field greenness, using a citizen science data entry platform, forensic palynology, as well as video guides, risk assessment and feedback forms were generated. Junior agriculture science students participated in the learning via online lessons and independent data collection in their own local neighborhood and/or school grounds situated within urban environments. The university research group and school coordinator, operating in their own distributed work environments, had to develop, source, adopt, and/or adapt material rapidly to meet the unique requirements of the project. The experience allowed two‐way knowledge exchange between the secondary and tertiary education sectors. Participating students were introduced to real‐world research and were able to engage in outdoor learning during a time when online, indoor, desk‐based learning dominated their studies. The unique context of restrictions imposed by the social isolation policies, as well as government Public Health and Department of Education directives, allowed the team to respond by adapting teaching and research activity to develop and trial learning modules and citizen science tools. The project provided a focus to motivate and connect teachers, academic staff, and school students during a difficult circumstance. Extension of this citizen project for the purposes of research and secondary school learning has the potential to offer ongoing benefits for grassland ecology data acquisition and student exposure to real‐world science.     

Budding biology teachers: what have botanical gardens got to offer inquiry learning

Teachers conceptualise inquiry learning in science learning differently. This is particularly evident when teachers are introduced to inquiry pedagogy within a new context. This exploratory study draws on semi-structured interviews conducted with eight pre-service secondary biology teachers following a day visit with university tutors to the Royal Botanical Gardens, Kew. Emerging findings were: first, pre-service biology teachers’ views of inquiry learning range in sophistication from simple notions of ‘learning from doing’ to complex multi-notions such as student generated questions, developing curiosity and encouraging authentic scientific practices. Second, similarly their views of inquiry learning opportunities in botanical gardens ranged from simply places that offered ‘memorable experiences’ to enabling autonomous learning due to the organism diversity and multiple climates. Pre-service teachers categorised as having unsophisticated views of inquiry learning had limited expectations of botanical gardens as productive learning environments. Third, the majority of pre-service teachers were concerned about managing inquiry learning. A tension was identified between how open-ended an inquiry activity could be whilst ensuring student focus. Further, participants were concerned about the practical management of inquiry learning. We discuss implications for teacher educators and botanical garden educators and the requirement for curriculum development and promotion.