How student teachers use scientific conceptions to discuss a complex environmental issue

This paper focuses upon the extent to which student teachers develop conceptual understanding about key scientific principles through their training, and the extent to which they can deploy this knowledge in discussions of complex environmental issues.

All students involved in the teacher-training programme answered a questionnaire — before and after their first term of the programme — in which their conceptions of respiration and photosynthesis were tested. 15 students were also interviewed about a newspaper article that discusses the ethicality of using surplus heat from a crematorium in the far heating system. They were asked to comment on the article, to pose questions about the issue and explicitly asked what happens to the bodies if either combusted or buried. The first results show that some students, though not the majority, develop their ability to answer conceptual questions about scientific content as a result of their first science course. However, even among these students, the task of deploying this conceptual understanding in discussions of complex, socially relevant questions proved very difficult. Most students expressed personal opinions without using scientific arguments. It may be that the students have not developed the ability to recognise and distinguish different contexts or that the learning situation has not been challenging enough.     

Enhancing Elementary Students’ Experiences Learning about Circuits Using an Exploration–Explanation Instructional Sequence

Using an exploration–explanation sequence of science instruction helps teachers unveil students’ prior knowledge about circuits and engage them in minds-on science learning. In these lessons, fourth grade students make predictions and test their ideas about circuits in series through hands-on investigations. The teacher helps students make connections between their hands-on experiences collecting data and new terms. This lesson shows how teachers can incorporate formative assessments such as checkpoints, self tests, and exit slips into the explanation phase of instruction so students can evaluate and self-monitor their understanding of circuits in series. These activities meet the National Science Education Standards for active, student-center learning environments that cultivate the critical thinking skills necessary to learn science.     

Learning genetics through an authentic research simulation in bioinformatics

Following the rationale that learning is an active process of knowledge construction as well as enculturation into a community of experts, we developed a novel web-based learning environment in bioinformatics for high-school biology majors in Israel. The learning environment enables the learners to actively participate in a guided inquiry process by solving a problem in the context of authentic research in genetics. Through the learning environment, the learners are exposed to a genetics problem which was developed on the basis of research in which a mutated gene, which causes deafness, was identified. They follow, step by step, the way scientists try to solve it, using the current geneticists' toolbox. The environment uses an adapted version of the BLAST program (a bioinformatics tool which enables to find similarities between sequences), which was modified in a way that enables the teachers and students to use it easily. Using quantitative and qualitative research approaches, we were able to show that learning through the bioinformatics environment promotes construction of new knowledge structures and influences students' acquisition of a deeper and multidimensional understanding of the genetics domain. In addition, learning through the bioinformatics environment influences students' comprehension of the practices and scientific ways of thinking.     

The effects of discovery learning in a lower-division biology course

This study investigated discovery learning pedagogy and its effects on students' achievement and attitudes toward instruction in a lower-division biology course, entitled Structure and Function of Organisms. Instruction was primarily lecture-based but included four discovery learning activities. Results indicate that students had greater achievement on content learned through discovery methods than lecture-based instruction. Findings regarding students' attitudes toward discovery-based instruction suggest that students enjoyed active, discovery-based problems, believed that discovery helped them gain an understanding of the material and helped them to develop skills that could be used in other courses. The study presented here shows that a moderate amount of discovery learning used in combination with traditional methods of instruction may be an effective means for promoting students' achievement.     

Teaching Tree Thinking to College Students: It’s Not as Easy as You Think

The ability to understand and reason with tree-of-life diagrams (i.e., cladograms), referred to as tree thinking, is an essential skill for biology students. Yet, recent findings indicate that cladograms are cognitively opaque to many college students, leading them to misinterpret the information depicted. The current studies address the impact of prior biological background and instruction in phylogenetics on students?? competence at two foundational tree-thinking skills. In Study 1, college students with stronger (N?=?52) and weaker (N?=?60) backgrounds in biology were asked to (a) identify all the nested clades in two cladograms and (b) evaluate evolutionary relatedness among taxa positioned at different hierarchical levels (two questions) and included in a polytomy (two questions). Stronger-background students were more successful than weaker-background students. In Study 2, a subset of the stronger-background students (N?=?41) who were enrolled in an evolution class subsequently received two days of instruction on phylogenetics. As expected, these students?? tree-thinking skills generally improved with instruction. However, although these students did very well at marking the nested clades, fundamental misinterpretations of relative evolutionary relatedness remained. The latter was especially, although not exclusively, the case for taxa included in a polytomy. These results highlight the importance of teaching cladistics, as well as the need to tailor such instruction to the difficulties students have learning key macroevolutionary concepts.     

Peer instruction enhanced meaningful learning: ability to solve novel problems

Students must be able to interpret, relate, and incorporate new information with existing knowledge and apply the new information to solve novel problems. Peer instruction is a cooperative learning technique that promotes critical thinking, problem solving, and decision-making skills. Therefore, we tested the hypothesis that peer instruction enhances meaningful learning or transfer, defined as the student's ability to solve novel problems or the ability to extend what has been learned in one context to new contexts. To test this hypothesis, our undergraduate exercise physiology class of 38 students was randomly divided into two groups: group A (n = 19) and group B (n = 19). A randomized crossover design in which students either answered questions individually or during peer instruction was used to control for time and order effects. The first factor that influences meaningful learning is the degree of mastery of the original material. Importantly, peer instruction significantly enhanced mastery of the original material. Furthermore, the student's ability to solve novel problems was significantly enhanced following peer instruction. Thus pausing two to three times during a 50-min class to allow peer instruction enhanced the mastery of the original material and enhanced meaningful learning, i.e., the student's ability to solve novel problems.     

Primary literature as a basis for a high-school biology curriculum

Textbooks, research news from the media, and review articles from popular journals are the most common sources of texts used for high-school biology education. We attempted to adopt primary literature as a means of developing scientific literacy among high-school biology majors. For that purpose, we developed and implemented a primary literature-based curriculum in developmental biology. The process of adapting original research articles to the high-school level, as well as a conversational model developed for learning through research articles, are discussed.     

Effects of different forms of physiology instruction on the development of students' conceptions of and approaches to science learning

The purpose of this study was to investigate students' conceptions of and approaches to learning science in two different forms: internet-assisted instruction and traditional (face-to-face only) instruction. The participants who took part in the study were 79 college students enrolled in a physiology class in north Taiwan. In all, 46 of the participants were from one class and 33 were from another class. Using a quasi-experimental research approach, the class of 46 students was assigned to be the "internet-assisted instruction group," whereas the class of 33 students was assigned to be the "traditional instruction group." The treatment consisted of a series of online inquiry activities. To explore the effects of different forms of instruction on students' conceptions of and approaches to learning science, two questionnaires were administered before and after the instruction: the Conceptions of Learning Science Questionnaire and the Approaches to Learning Science Questionnaire. Analysis of covariance results revealed that the students in the internet-assisted instruction group showed less agreement than the traditional instruction group in the less advanced conceptions of learning science (such as learning as memorizing and testing). In addition, the internet-assisted instruction group displayed significantly more agreement than the traditional instruction group in more sophisticated conceptions (such as learning as seeing in a new way). Moreover, the internet-assisted instruction group expressed more orientation toward the approaches of deep motive and deep strategy than the traditional instruction group. However, the students in the internet-assisted instruction group also showed more surface motive than the traditional instruction group did.     

基于QQ平台开展微生物学项目学习的探索

将QQ平台与项目学习整合引入微生物学教学中,开展基于QQ平台的教学探索。教师首先通过QQ群文件夹发布项目学习选题,然后根据项目活动的进程利用QQ群文件夹、QQ一对一文件传输功能给学生传送项目活动相关的文档或发布学习资料,并通过QQ聊天功能解答学生的疑难问题、督促学生开展项目学习活动。问卷调查结果表明:基于QQ平台的微生物学项目学习有利于发挥学生学习的主体性,能够加强师生之间的交流,提高学生的学习兴趣、信息素养及协作学习能力。     

A participatory learning approach to biochemistry using student authored and evaluated multiple-choice questions

A participatory learning approach, combined with both a traditional and a competitive assessment, was used to motivate students and promote a deep approach to learning biochemistry. Students were challenged to research, author, and explain their own multiple-choice questions (MCQs). They were also required to answer, evaluate, and discuss MCQs written by their peers. The technology used to support this activity was PeerWise--a freely available, innovative web-based system that supports students in the creation of an annotated question repository. In this case study, we describe students' contributions to, and perceptions of, the PeerWise system for a cohort of 107 second-year biomedical science students from three degree streams studying a core biochemistry subject. Our study suggests that the students are eager participants and produce a large repository of relevant, good quality MCQs. In addition, they rate the PeerWise system highly and use higher order thinking skills while taking an active role in their learning. We also discuss potential issues and future work using PeerWise for biomedical students.     

El Carnival de Mitosis

Teachers as well as students often have difficulty formulating good research questions because not all questions lend themselves to scientific investigation. The following is a guide for high-school and college life-science teachers to help students define question types central to biological field studies. The mayfly nymph was selected as the example study organism because they are common in warm humid climates worldwide and are used as key indicators of water quality and stream health. Assessment of students’ work should be a logical extension field investigations. Assessment simply using traditional multiple-choice items after research investigations communicates to students that recall of specific facts (declarative knowledge) is important and investigative processes (procedural knowledge) are not important. Assessment of declarative knowledge should not be ignored, but procedural knowledge should be included. Both are important to science literacy.     

Good student questions in inquiry learning

Acquisition of scientific reasoning is one of the big challenges in education. A popular educational strategy advocated for acquiring deep knowledge is inquiry-based learning, which is driven by emerging ‘good questions’. This study will address the question: ‘Which design features allow learners to refine questions while preserving student ownership of the inquiry process?’ This design-based research has been conducted over several years with advanced high-school biology classes. The results confirm the central role of question elaboration as an interactive process that leads from vague to complex and adequate. To make this happen, the inquiry process must extend over a long time, learners and teachers should share a knowledge improvement goal, and text produced by students should be structured by question–answer pairs addressing a single concept using authentic resources. Further features are discussion with peers, teacher feedback with respect to answer elaboration and conceptual differentiation, and finally, teacher guidance that should fade out in successive inquiry cycles to ensure student responsibility.     

Building a Research Agenda for Indigenous Epistemologies and Education

One emergent issue in relation to research on Indigenous epistemologies and education concerns the extent to which Indigenous epistemologies lead to new kinds of educational experiences and outcomes and pose new research questions. This commentary responds to the sense of limits and possibilities for Indigenous education that are raised by the research in this theme issue, and suggests that there are indeed new questions to be asked and answered through research.     

An inquiry-based learning model for an exercise physiology laboratory course

We developed an inquiry-based learning model to better stimulate undergraduate students' cognitive development of exercise physiology laboratory concepts. The course core is the two independent research projects that students, working in small groups, complete during the last 9 wk of the semester. Student groups develop their own research question and hypothesis, design the experiment, collect and analyze the data, and report their findings to the rest of the class using presentation software. To help with success of the research projects, students are taken through a series of guided-inquiry laboratory activities during the initial 6 wk of the semester to develop laboratory skills and an understanding of the scientific process. Observations of student behaviors reflected a high level of enthusiasm and engagement in laboratory activities. Surveys, journal entries, and interviews indicated that students felt empowered by having ownership in their projects, which may be the key reason for the success of this model.     

Botanical literacy: What and how should students learn about plants?

Botanists benefit from a scientifically literate society and an interested and botanically literate student population, and we have opportunities to promote literacy in our classes. Unfortunately, scientific illiteracy exists, in part, because students are technologically advanced but lack intellectual curiosity and rigor. Botanical illiteracy results from several interacting factors, including a lack of interest in plants and infrequent exposure to plant science before students reach college. If scientific or botanical literacy is a goal, we must understand what literacy means and how we can help students reach that goal. A model of biological literacy recognizes four levels; students enter courses at the lowest level possessing misconceptions about concepts; however, misconceptions can be used to our advantage, especially by using concept inventories. Inquiry-based instruction is advocated for all science courses, and learning theory supports inquiry. Seven principles of learning inform recommendations about how botanists should teach, including using themes and "thinking botanically" to illustrate all biological concepts. Overall, consideration of the botanical content taught is less critical than the methods used to teach that content. If botanists emphasize thinking and process skills with an understanding of concepts, we will prepare scientifically literate students and citizens and benefit from our efforts.     

An online tutorial for helping nonscience majors read primary research literature in biology

Using primary literature is an effective tool for promoting active learning and critical thinking in science classes. However, it can be challenging to use primary literature in large classes and in classes for nonscience majors. We describe the development and implementation of an online tutorial for helping nonscience majors learn to read primary literature in biology. The tutorial includes content about the scientific process and the structure of scientific papers and provides opportunities for students to practice reading primary literature. We describe the use of the tutorial in Biology of Exercise, a course for nonscience majors. Students used the tutorial outside of class to learn the basic principles involved in reading scientific papers, enabling class sessions to focus on active-learning activities and substantive class discussions.     

The Greatest Learning Return on Your Pedagogical Investment: Alignment,Assessment or In-Class Instruction?

Critical thinking is often considered an essential learning outcome of institutions in higher education. Previous work has proposed three pedagogical strategies to address this goal: more active, student-centered in-class instruction, assessments which contain higher-order cognitive questions, and greater alignment within a classroom (i.e., high agreement of the cognitive level of learning objectives, assessments, and in-class instruction). Our goals were to determine which of these factors, individually or the interactions therein, contributed most to improvements in university students’ critical thinking. We assessed students’ higher-order cognitive skills in introductory non-majors biology courses the first and last week of instruction. For each of the fifteen sections observed, we also measured the cognitive level of assessments and learning objectives, evaluated the learner-centeredness of each classroom, and calculated an alignment score for each class. The best model to explain improvements in students’ high-order cognitive skills contained the measure of learner-centeredness of the class and pre-quiz scores as a covariate. The cognitive level of assessments, learning objectives, nor alignment explained improvements in students’ critical thinking. In accordance with much of the current literature, our findings support that more student-centered classes had greater improvements in student learning. However, more research is needed to clarify the role of assessment and alignment in student learning.     

启发式思考题对医学本科分子生物学实验教学的促进作用

目的:通过自行设计的启发式思考题,让问题式学习伴随医学生分子生物学实验教学全程,利用实验课的教学互动环节发挥学生学习的主观能动性。方法:借鉴启发式教学经验和问题式教学方法,在实验的平时考核中增加了启发式思考题,针对教学内容设置拓展性问题,以开卷回答的方式引导学生通过自学寻找操作实践及其理论基础中潜在的知识内涵和科学规律。结果:思考题的引入在强化学生自主学习,锻炼思考和解决问题能力的同时也显示出了良好的区分度。思考题成绩以及以此为基础的平时成绩与实验理论考核成绩之间显示出了显著的相关性。结论:贯穿于实验课教学活动中的启发式思考题在拓展思维、提升学生自主学习能力的同时促进了实验课的教学效果。     

Biology student teachers’ dialogic talk in inquiry-based instruction

ABSTRACT

Inquiry-based learning has generally accepted by scholars as a most effective teaching approach in biology education. The talk during inquiry-based teaching needs to be practiced. There is less evidence how student teachers talk with students during their inquiry-based biology instruction. This knowledge is needed in supporting student teachers to develop their teachership in biology education. In this qualitative case study, the dialogic talk of biology student teachers (N = 6) was studied in the context of inquiry-based lessons in lower secondary school. The student teachers’ lessons were video and audio recorded and the data was analyzed using content analysis. The student teachers used dialogic talk in their inquiry-based instruction only occasionally, mainly in the examination and the conclusion stages. During the introduction stage, dialogic talk was less used and it was mainly explaining and instructing the content. In the examination stage, student teachers also guided students and stated facts. During the conclusion stage, student teachers mainly explained and also evaluated students’ statements. The lesson’s topics and methods used in inquiry-based learning may enable the dialogic talk of student teacher to some extent. However, teacher education should focus more on scaffolding student teachers’ talk with their students in all kinds of inquiry approaches.     

慕课背景下“微生物工程”实验课开放式教学模式探索

慕课等线上学习平台是教育信息化的结果,结合慕课对传统教学进行突破是近年来教学改革的热点之一.“微生物工程”课程是高等院校生物技术、生物工程专业的必修课,该课程具有很强的应用性和实践性.为了加深学生对理论知识的理解、培养学生的科研思维,我们在微生物工程实验课的教学中引入了一种基于慕课教学资源的开放式教学模式.结果 表明,...