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1.
Over the past decade, repeated calls have been made to incorporate more active teaching and learning in undergraduate biology courses. The emphasis on inquiry-based teaching is especially important in laboratory courses, as these are the courses in which students are applying the process of science. To determine the current state of research on inquiry-based teaching in undergraduate biology laboratory courses, we reviewed the recent published literature on inquiry-based exercises. The majority of studies in our data set were in the subdisciplines of biochemistry, cell biology, developmental biology, genetics, and molecular biology. In addition, most exercises were guided inquiry, rather than open ended or research based. Almost 75% of the studies included assessment data, with two-thirds of these studies including multiple types of assessment data. However, few exercises were assessed in multiple courses or at multiple institutions. Furthermore, assessments were rarely based on published instruments. Although the results of the studies in our data set show a positive effect of inquiry-based teaching in biology laboratory courses on student learning gains, research that uses the same instrument across a range of courses and institutions is needed to determine whether these results can be generalized. 相似文献
2.
Katerina V. Thompson K?ren C. Nelson Gili Marbach-Ad Michael Keller William F. Fagan 《CBE life sciences education》2010,9(3):277-283
There is widespread agreement within the scientific and education communities that undergraduate biology curricula fall short in providing students with the quantitative and interdisciplinary problem-solving skills they need to obtain a deep understanding of biological phenomena and be prepared fully to contribute to future scientific inquiry. MathBench Biology Modules were designed to address these needs through a series of interactive, Web-based modules that can be used to supplement existing course content across the biological sciences curriculum. The effect of the modules was assessed in an introductory biology course at the University of Maryland. Over the course of the semester, students showed significant increases in quantitative skills that were independent of previous math course work. Students also showed increased comfort with solving quantitative problems, whether or not they ultimately arrived at the correct answer. A survey of spring 2009 graduates indicated that those who had experienced MathBench in their course work had a greater appreciation for the role of mathematics in modern biology than those who had not used MathBench. MathBench modules allow students from diverse educational backgrounds to hone their quantitative skills, preparing them for more complex mathematical approaches in upper-division courses. 相似文献
3.
Assessment of the effects of student response systems on student learning and attitudes over a broad range of biology courses 总被引:2,自引:0,他引:2
With the advent of wireless technology, new tools are available that are intended to enhance students' learning and attitudes. To assess the effectiveness of wireless student response systems in the biology curriculum at New Mexico State University, a combined study of student attitudes and performance was undertaken. A survey of students in six biology courses showed that strong majorities of students had favorable overall impressions of the use of student response systems and also thought that the technology improved their interest in the course, attendance, and understanding of course content. Students in lower-division courses had more strongly positive overall impressions than did students in upper-division courses. To assess the effects of the response systems on student learning, the number of in-class questions was varied within each course throughout the semester. Students' performance was compared on exam questions derived from lectures with low, medium, or high numbers of in-class questions. Increased use of the response systems in lecture had a positive influence on students' performance on exam questions across all six biology courses. Students not only have favorable opinions about the use of student response systems, increased use of these systems increases student learning. 相似文献
4.
Three approaches to molecular phylogenetics are demonstrated to biology students as they explore molecular data from Homo sapiens and four related primates. By analyzing DNA sequences, protein sequences, and chromosomal maps, students are repeatedly challenged to develop hypotheses regarding the ancestry of the five species. Although these exercises were designed to supplement and enhance classroom instruction on phylogeny, cladistics, and systematics in the context of a postsecondary majors-level introductory biology course, the activities themselves require very little prior student exposure to these topics. Thus, they are well suited for students in a wide range of educational levels, including a biology class at the secondary level. In implementing this exercise, we have observed measurable gains, both in student comprehension of molecular phylogeny and in their acceptance of modern evolutionary theory. By engaging students in modern phylogenetic activities, these students better understood how biologists are currently using molecular data to develop a more complete picture of the shared ancestry of all living things. 相似文献
5.
This paper estimates the causal effect of taking a course in quantitative reasoning on students’ academic performance and classroom peer-group composition at a liberal arts college. To identify effects, the paper compares the outcomes of otherwise similar students who barely passed a baseline quantitative skills assessment (not taking the course) with students who barely failed (taking the course). The regression-discontinuity estimates show little impact on academic outcomes for student close to the passing cutoff, including grades on subsequent courses with quantitative content, but we are unable to distinguish small from zero effects. Exogenous course assignment does affect the composition of students’ classroom peer groups in subsequent years. The effects can only be generalized to students in the vicinity of the passing threshold (but not students with much worse quantitative skills at the baseline). We discuss implications for research and policy on remediation. 相似文献
6.
There is increasing enthusiasm for teaching approaches that combine mathematics and biology. The call for integrating more quantitative work in biology education has led to new teaching tools that improve quantitative skills. Little is known, however, about whether increasing interdisciplinary work can lead to adverse effects, such as the development of broader but shallower skills or the possibility that math anxiety causes some students to disengage in the classroom, or, paradoxically, to focus so much on the mathematics that they lose sight of its application for the biological concepts in the center of the unit at hand. We have developed and assessed an integrative learning module and found disciplinary learning gains to be equally strong in first-year students who actively engaged in embedded quantitative calculations as in those students who were merely presented with quantitative data in the context of interpreting biological and biostatistical results. When presented to advanced biology students, our quantitative learning tool increased test performance significantly. We conclude from our study that the addition of mathematical calculations to the first year and advanced biology curricula did not hinder overall student learning, and may increase disciplinary learning and data interpretation skills in advanced students. 相似文献
7.
University Modeling Instruction (UMI) is an approach to curriculum and pedagogy that focuses instruction on engaging students in building, validating, and deploying scientific models. Modeling Instruction has been successfully implemented in both high school and university physics courses. Studies within the physics education research (PER) community have identified UMI''s positive impacts on learning gains, equity, attitudinal shifts, and self-efficacy. While the success of this pedagogical approach has been recognized within the physics community, the use of models and modeling practices is still being developed for biology. Drawing from the existing research on UMI in physics, we describe the theoretical foundations of UMI and how UMI can be adapted to include an emphasis on models and modeling for undergraduate introductory biology courses. In particular, we discuss our ongoing work to develop a framework for the first semester of a two-semester introductory biology course sequence by identifying the essential basic models for an introductory biology course sequence. 相似文献
8.
This study examined differences in students’ classroom motivational climate perceptions and motivational beliefs between those enrolled in undergraduate Biology courses that implemented an innovative, active learning intervention and those enrolled in traditional Biology courses (control group). This study also sought to determine whether students’ classroom motivational climate perceptions and motivational beliefs mediated the effect of the intervention on course grades. Participants were 962 college students attending a large US public university. Students self-selected into one of the biology courses were randomly assigned to the intervention or control group. Multiple regression analyses indicated that students receiving the intervention reported greater instructor support, a perception of higher expectations for understanding (academic press), and a greater feeling that the course was interesting (situational interest). They also held higher self-efficacy and value for their biology course at completion compared to their counterparts in traditional biology classrooms. Moreover, mediation analyses indicated that the effect of the intervention on course grades was better explained through students’ classroom motivational climate perceptions and motivational beliefs. Results gained from this intervention may be useful to other campuses interested in enhancing student motivation and success even when faced with large enrolments and minimal faculty and staff support. 相似文献
9.
Undergraduate biology education is often viewed as being focused on memorization rather than development of students’ critical-thinking abilities. We speculated that open-note testing would be an easily implemented change that would emphasize higher-order thinking. As open-note testing is not commonly used in the biological sciences and the literature on its effects in biology education is sparse, we performed a comprehensive analysis of this intervention on a primary literature–based exam across three large-enrollment laboratory courses. Although students believed open-note testing would impact exam scores, we found no effect on performance, either overall or on questions of nearly all Bloom’s levels. Open-note testing also produced no advantage when examined under a variety of parameters, including research experience, grade point average, course grade, prior exposure to primary literature–focused laboratory courses, or gender. Interestingly, we did observe small differences in open- and closed-note exam performance and perception for students who experienced open-note exams for an entire quarter. This implies that student preparation or in-test behavior can be altered by exposure to open-note testing conditions in a single course and that increased experience may be necessary to truly understand the impact of this intervention. 相似文献
10.
Jennifer G. Cromley Tony C. Perez Shannon L. Fitzhugh Nora S. Newcombe Theodore W. Wills Jacqueline C. Tanaka 《Journal of Experimental Education》2013,81(4):511-537
The authors tested whether students can be taught to better understand conventional representations in diagrams, photographs, and other visual representations in science textbooks. The authors developed a teacher-delivered, workbook-and-discussion–based classroom instructional method called Conventions of Diagrams (COD). The authors trained 1 experienced teacher to deliver COD to two 10th-grade biology classes (n = 31) and compared gains in diagram comprehension from COD to those from a business-as-usual control condition (n = 30) in 2 classrooms taught by the same teacher. Students in the COD condition showed statistically significantly greater growth in comprehension of literal and inferential biology diagrams. The control condition in some cases advantaged high-spatial, high-knowledge students, whereas the COD condition for the most part did not. Entries in the COD workbooks were analyzed for amount of student effort. Students with a combination of low pretest biology knowledge and low effort showed much lower gains from pretest to posttest on the inferential biology diagrams measure than did other students in the COD condition. 相似文献
11.
This paper describes a newly adapted instrument for measuring novice-to-expert-like perceptions about biology: the Colorado Learning Attitudes about Science Survey for Biology (CLASS-Bio). Consisting of 31 Likert-scale statements, CLASS-Bio probes a range of perceptions that vary between experts and novices, including enjoyment of the discipline, propensity to make connections to the real world, recognition of conceptual connections underlying knowledge, and problem-solving strategies. CLASS-Bio has been tested for response validity with both undergraduate students and experts (biology PhDs), allowing student responses to be directly compared with a consensus expert response. Use of CLASS-Bio to date suggests that introductory biology courses have the same challenges as introductory physics and chemistry courses: namely, students shift toward more novice-like perceptions following instruction. However, students in upper-division biology courses do not show the same novice-like shifts. CLASS-Bio can also be paired with other assessments to: 1) examine how student perceptions impact learning and conceptual understanding of biology, and 2) assess and evaluate how pedagogical techniques help students develop both expertise in problem solving and an expert-like appreciation of the nature of biology. 相似文献
12.
Bradley W. Bergey Jennifer G. Cromley Nora S. Newcombe 《International Journal of Science Education》2013,35(15):2476-2502
There is growing evidence that targeted instruction can improve diagram comprehension, yet one of the skills identified in the diagram comprehension literature—coordinating multiple representations—has rarely been directly taught to students and tested as a classroom intervention. We created a Coordinating Multiple Representation (CMR) intervention that was an addition to an intervention focused on Conventions of Diagrams (COD) and tested their joint effects on diagram comprehension for near transfer (uninstructed biology diagrams), far transfer (uninstructed geology diagrams), and content learning (biology knowledge). The comparison group received instruction using a previously validated intervention that focused exclusively on COD. Participants were 9th–10th grade biology students (N?=?158 from two schools), whose classes were randomly assigned to COD alone or COD?+?CMR conditions and studied with a pretest–posttest experimental design. Both groups showed significant growth in biology knowledge (d?=?.30–.53, for COD and COD?+?CMR, respectively) and biology diagram comprehension (d?=?.28–.57). Neither group showed far transfer. Analyses of student work products during the interventions suggest that gains were not simply due to the passage of time, because student effort was correlated with gains in both treatment groups. Directions for improving future CMR interventions are discussed. 相似文献
13.
Scott B. Waltz 《Mentoring & Tutoring: Partnership in Learning》2019,27(1):26-43
The aim of my study was: (a) to measure the effectiveness of a supporting tutor-training curriculum and content knowledge gains for preservice teachers engaged in service learning and (b) to determine whether tutor training and field experience improved the preservice teachers’ teaching self-efficacy beliefs. One hundred and thirteen upper-division undergraduate students enrolled in Social Foundations of Multicultural Education courses participated in course-embedded tutor-training and fulfilled a 20-h service-learning requirement by tutoring pupils in local elementary schools. Analyses of variance (ANOVA) on a pretest and posttest measures of content knowledge, tutoring skills, and teaching self-efficacy demonstrated a statistically significant difference with higher mean scores at the post time. These results suggest that a course-specific tutor-training curriculum advances the participants’ knowledge and skill in tutoring. The results also indicate that the combination of tutor training and field application (i.e. tutoring in a classroom) function to increase students’ self-efficacy as future teachers. 相似文献
14.
Dionne Cross Gita Taasoobshirazi Sean Hendricks Daniel T. Hickey 《International Journal of Science Education》2013,35(6):837-861
In this paper we explore the relationship between learning gains, measured through pre‐assessment and post‐assessment, and engagement in scientific argumentation. In order to do so, this paper examines group discourse and individual learning during the implementation of NASA Classroom of the Future’s BioBLAST!® (BB) software program in a high school biology classroom. We found that the argumentative structures, the quality of these structures, and the identities that students take on during collaborative group work are critical in influencing student learning and achievement in science. We provide recommendations for instructors implementing argumentation in their science classrooms, and provide suggestions for the development of future research in this area. 相似文献
15.
More than a picture: helping undergraduates learn to communicate through scientific images 总被引:1,自引:0,他引:1 
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下载免费PDF全文 Images are powerful means of communicating scientific results; a strong image can underscore an experimental result more effectively than any words, whereas a poor image can readily undermine a result or conclusion. Developmental biologists rely extensively on images to compare normal versus abnormal development and communicate their results. Most undergraduate lab science courses do not actively teach students skills to communicate effectively through images. To meet this need, we developed a series of image portfolio assignments and imaging workshops in our Developmental Biology course to encourage students to develop communication skills using images. The improvements in their images over the course of the semester were striking, and on anonymous course evaluations, 73% of students listed imaging skills as the most important skill or concept they learned in the course. The image literacy skills acquired through simple lab assignments and in-class workshops appeared to stimulate confidence in the student's own evaluations of current scientific literature to assess research conclusions. In this essay, we discuss our experiences and methodology teaching undergraduates the basic criteria involved in generating images that communicate scientific content and provide a road map for integrating this curriculum into any upper-level biology laboratory course. 相似文献
16.
In this study, the following questions were addressed in an undergraduate non-major biology course using a large lecture format: Is there a relationship between students?? perceptions of their learning environment and course performance, and what roles do motivation and attitudes play in mediating that relationship? The purpose of this study was to test a path model describing the mediating effects of motivation and attitudes on learning environments and course performance. The study considered contemporary understanding of teaching and learning, as well as motivation and attitudes, in suggesting a direction for future reform efforts and to guide post-secondary science education instructors and leaders in the design of learning environments for undergraduate non-major biology courses. Among the classroom learning environment variables assessed in this study, personal relevance was the major contributor to predicting attitudes, motivation and course performance. Although the classroom learning environment had a very weak direct effect on course performance, there was a moderate total effect on self-efficacy and intrinsic goal orientation. The classroom learning environment also had a moderate total effect on attitudes toward biology. Attitudes toward biology had a moderate direct effect on self-efficacy. While attitudes toward biology was significantly correlated with course performance, the direct effect was extremely weak and was dropped from the model. However, attitudes toward biology had a moderate indirect effect on course performance due to the mediating effects of self-efficacy. Self-efficacy had a strong direct effect on course performance and therefore seemed to be particularly important. The model tested in this study explained 33?% of the variance in course performance, 56?% of the variance in self-efficacy, 24?% of the variance in attitudes toward biology, and 18?% of the variance in intrinsic goal orientation. To improve course performance, instructors should focus on building self-efficacy among their students and ensure that students find the course personally relevant. 相似文献
17.
陈栋 《乐山师范学院学报》2013,28(3):128-131
新课程改革强调培养学生的创新能力和创造性思维,而科学课程能激发学生的学习兴趣和求知欲望,通过实践活动能够显著培养其科学思维能力。借鉴国外课程经验可知,农村小学科学课程建设既是国家战略与农村发展的需要,又有利于学生全面发展与创新精神的培养及其主动学习与价值评判的形成。农村小学科学课程建设应当遵循以下路径:着重于科学课程资源开发与管理,关注科学课程的动态生成,构建和谐高效的科学课堂。 相似文献
18.
Introductory biology courses are frequently offered separately to biology majors and nonbiology majors, with the assumption that the two groups of students are different enough to merit different courses. To assess the evidence behind this assumption, we compared students in two different genetics classes at the University of Colorado–Boulder, one class for nonscience majors (nonmajors) and the other class for biology majors and students planning a biology-related career (majors), to see whether these two groups of students were fundamentally different in performance and attitudes. To measure content knowledge, we administered identical assessments to both groups of students during the semester: a validated pre- and postcontent assessment (Genetics Concept Assessment), ungraded quizzes after problem-solving sessions, and questions on each exam. We measured attitudes, study time, and study techniques through online surveys. Majors outperformed nonmajors on content assessments, finishing with significantly higher learning gains. Nonmajors and majors also differed in their motivation, interest, study time, and expert-level of beliefs. We suggest that focusing on the process of science and its connection to students'' lives will better engage and motivate nonmajors while still helping them learn the fundamental concepts of genetics. 相似文献
19.
Now visualization courses have been taught at universities around the world. Keeping students motivated and actively engaged in this course can be a challenging task. In this paper we introduce our developed interactive learning system called VisMis (Visualization and Multi-modal Interaction System) for postgraduate scientific visualization course at Beijing Normal University. We develop it following the Great Didactic from Comenius and the theory of constructivism on constructing the visual and interactive learning environment to support and challenge the student’s learning. We give a report on our proprietary system including its educational objective, volume visualization module, multi-modal interaction module, and CUDA implementation etc. By the evaluation, we conclude that VisMis is an innovative platform for volume visualization with novel transfer function design and multi-modal interaction. It has more advantage in easiness, speed, layer control, interaction, etc. 相似文献
20.
Supplemental instruction classes have been shown in many studies to enhance performance in the supported courses and even to improve graduation rates. Generally, there has been little evidence of a differential impact on students from different ethnic/racial backgrounds. At San Francisco State University, however, supplemental instruction in the Introductory Biology I class is associated with even more dramatic gains among students from underrepresented minority populations than the gains found among their peers. These gains do not seem to be the product of better students availing themselves of supplemental instruction or other outside factors. The Introductory Biology I class consists of a team-taught lecture component, taught in a large lecture classroom, and a laboratory component where students participate in smaller lab sections. Students are expected to master an understanding of basic concepts, content, and vocabulary in biology as well as gain laboratory investigation skills and experience applying scientific methodology. In this context, supplemental instruction classes are cooperative learning environments where students participate in learning activities that complement the course material, focusing on student misconceptions and difficulties, construction of a scaffolded knowledge base, applications involving problem solving, and articulation of constructs with peers. 相似文献