Little intervention,big results: intentional integration of information literacy into an introductory-level biology lab course

Abstract

Information literacy refers to a set of skills that allow its user to find appropriate resources and use them to develop, define and defend arguments. In many undergraduate programms, including biology and STEM related fields, students are expected to utilise these skills in writing lab reports, paper analyses, and in developing testable hypotheses. Here, we describe the development of a formalised information literacy module for an introductory biology laboratory course and a rubric to measure the effectiveness of this module, including suggestions for implementation. Our data show that while short-term gains were not made using previously published IL tests, application of a tailored rubric to writing assignments did show significant improvement in the students’ ability to find relevant sources, define the purpose of their work and explore that focus. The results of our evaluation demonstrate that even modest additions of formal instruction in information literacy to a course can significantly improve student gains in this area.     

Project-based learning in a collaborative group can enhance student skill and ability in the biochemical laboratory: a case study

ABSTRACT

Experimental courses for undergraduate students majoring in biochemistry or related subjects often do not provide students with systematic and research-based experiences. To help students develop abilities related to laboratory techniques, data analysis, and systematic thought in biology, we performed an exploratory program that employs project-based learning in collaborative groups. The participants (total of 18 students) organized themselves into groups of 2–4 students, and each group researched an enzyme that had not been described previously. The program began with a literature survey of enzyme and bioinformatics analysis. The students cloned the gene encoding the enzyme, purified the enzyme, and, finally, analyzed the enzyme’s catalytic characteristics. The students explained the catalytic mechanism, integrating their experimental data and other knowledge. An instructor provided support and training during the process to support effective teamwork and to cultivate a habit of independence that is believed to be useful for the students’ future careers. The assessment showed that the pilot program yielded an improvement in the participant’ laboratory skills, scientific presentation ability, and experimental design ability. These analyses indicated that the small-scale practice in this study provided benefits to the students and the methods may be popularized to a large extent.     

“七步法”课堂设计与实践：构建研究导向型微生物学“金课”课堂

研究导向型教学是以学生成长和发展为中心的创新性教育模式，其核心目标与“金课”的建设目标一致，强调培养学生的研究技能，使其具有创新性和高阶性。在微生物学一流课程建设过程中，将研究导向型教学理念与BOPPPS课堂[导入(bridge-in)、目标(objective)、前测(pre-assessment)、参与式学习(participatory-learning)、后测(post-assessment)和总结(summary)]组织形式相结合，并创新性引入“提升”模块，以问题为驱动，聚焦科学前沿，融入思政材料，形成导入—目标—前测—参与式学习—后测—提升—总结(七步法)的新型模块化闭环教学模式。该模式的实施能够有效提升课堂教学的逻辑性和组织性，提高教学效率，提升学生分析问题和解决问题的高阶性，为学生将来开展科研工作奠定良好的基础，并为打造以学生为中心的“金课”课堂实践提供借鉴参考。     

The essence of student visual-spatial literacy and higher order thinking skills in undergraduate biology

Science, engineering and mathematics-related disciplines have relied heavily on a researcher's ability to visualize phenomena under study and being able to link and superimpose various abstract and concrete representations including visual, spatial, and temporal. The spatial representations are especially important in all branches of biology (in developmental biology time becomes an important dimension), where 3D and often 4D representations are crucial for understanding the phenomena. By the time biology students get to undergraduate education, they are supposed to have acquired visual-spatial thinking skills, yet it has been documented that very few undergraduates and a small percentage of graduate students have had a chance to develop these skills to a sufficient degree. The current paper discusses the literature that highlights the essence of visual-spatial thinking and the development of visual-spatial literacy, considers the application of the visual-spatial thinking to biology education, and proposes how modern technology can help to promote visual-spatial literacy and higher order thinking among undergraduate students of biology.     

Teaching Tree-Thinking to Undergraduate Biology Students

Evolution is the unifying principle of all biology, and understanding how evolutionary relationships are represented is critical for a complete understanding of evolution. Phylogenetic trees are the most conventional tool for displaying evolutionary relationships, and “tree-thinking” has been coined as a term to describe the ability to conceptualize evolutionary relationships. Students often lack tree-thinking skills, and developing those skills should be a priority of biology curricula. Many common student misconceptions have been described, and a successful instructor needs a suite of tools for correcting those misconceptions. I review the literature on teaching tree-thinking to undergraduate students and suggest how this material can be presented within an inquiry-based framework.     

Using a course-long theme for inquiry-based laboratories in a comparative physiology course

I developed an inquiry-based laboratory model that uses a central theme throughout the semester to develop in undergraduate biology majors the skills required for conducting science while introducing them to modern and classical physiological techniques. The physiology laboratory uses a goal-oriented approach, with students working cooperatively in small groups to answer basic biological questions. The student teams work to develop skills associated with experimental design, data analysis, written and oral communication, science literacy, and critical thinking. The laboratory curriculum is a research-based model that offers the advantage of students asking open-ended questions by use of a variety of techniques. For the students and instructor alike, this presents an exciting and challenging approach for learning physiology and basic biological principles. Another advantage of this laboratory model is that it is flexible and adaptable; the central theme can be any that the instructor chooses, and the goals and techniques developed are based on student and instructor needs and interests. Students who have completed this model at Loyola College in Maryland have become equipped with the skills essential for any area of the biological sciences and, most importantly, showed elevated excitement and commitment to learning.     

Transposing from the Laboratory to the Classroom to Generate Authentic Research Experiences for Undergraduates

Large lecture classes and standardized laboratory exercises are characteristic of introductory biology courses. Previous research has found that these courses do not adequately convey the process of scientific research and the excitement of discovery. Here we propose a model that provides beginning biology students with an inquiry-based, active learning laboratory experience. The Dynamic Genome course replicates a modern research laboratory focused on eukaryotic transposable elements where beginning undergraduates learn key genetics concepts, experimental design, and molecular biological skills. Here we report on two key features of the course, a didactic module and the capstone original research project. The module is a modified version of a published experiment where students experience how virtual transposable elements from rice (Oryza sativa) are assayed for function in transgenic Arabidopsis thaliana. As part of the module, students analyze the phenotypes and genotypes of transgenic plants to determine the requirements for transposition. After mastering the skills and concepts, students participate in an authentic research project where they use computational analysis and PCR to detect transposable element insertion site polymorphism in a panel of diverse maize strains. As a consequence of their engagement in this course, students report large gains in their ability to understand the nature of research and demonstrate that they can apply that knowledge to independent research projects.     

The essence of student visual–spatial literacy and higher order thinking skills in undergraduate biology

Science, engineering and mathematics-related disciplines have relied heavily on a researcher’s ability to visualize phenomena under study and being able to link and superimpose various abstract and concrete representations including visual, spatial, and temporal. The spatial representations are especially important in all branches of biology (in developmental biology time becomes an important dimension), where 3D and often 4D representations are crucial for understanding the phenomena. By the time biology students get to undergraduate education, they are supposed to have acquired visual–spatial thinking skills, yet it has been documented that very few undergraduates and a small percentage of graduate students have had a chance to develop these skills to a sufficient degree. The current paper discusses the literature that highlights the essence of visual–spatial thinking and the development of visual–spatial literacy, considers the application of the visual–spatial thinking to biology education, and proposes how modern technology can help to promote visual–spatial literacy and higher order thinking among undergraduate students of biology.     

Undergraduate geriatric education through community service learning

doi: 10.1111/j.1741‐2358.2010.00444.x Undergraduate geriatric education through community service learning Introduction: Despite the exponential growth of the elderly population worldwide, geriatric education has been a formal component of only a few dental schools’ curricula. Objective: To describe the geriatric community service learning (CSL) component of the professionalism and community service (PACS) module, and to explore a CSL project carried out by a group of first year dental students at a long‐term care facility. Methods: A literature review was performed to present and describe the CSL component of the PACS module. Students’ personal reflections were used to illustrate some of the joys and challenges of experiencing a long‐term care facility environment. Results: The newly developed PACS module combines community service learning with the long‐term care experience. Students develop, apply and evaluate an educational health promotion activity in a long‐term care facility. Conclusions: The PACS module has encouraged students to acquire comprehensive knowledge and awareness of the needs and dynamics of a long‐term care as they collaboratively interacted with personnel from the facility to develop their projects. The authors would like to engage other schools in discussing the need to integrate community‐based geriatric education into their dental curricula.     

Evaluating Sex and Gender Competencies in the Medical Curriculum: A Case Study

BackgroundSex and gender differences exist in the manifestation and prevalence of many conditions and diseases. Yet many clinician training programs neglect to integrate this information across their curricula.ObjectiveThis study aimed to measure the sex and gender medical knowledge of medical students enrolled in a program without an explicit directive to integrate sex and gender differences across a block system of core subjects.MethodsA forced-choice instrument consisting of 35 multiple-choice and true or false questions was adapted from an evaluation tool used in the European Curriculum in Gender Medicine held at Charité Hospital, Berlin, in September 2010.ResultsFourth-year (response rate 93%) and second-year (response rate 70%) students enrolled in Mayo Medical School completed the instrument. More than 50% of students in both classes indicated that topics related to sex and gender were covered in gynecology, cardiology, and pediatrics, and <20% of students indicated inclusion of such topics in nephrology, neurology, and orthopedics. More than twice as many second-year students indicated that topics dealing with sex and gender were included in immunology course material compared with fourth-year students. A consensus of written comments indicated that concepts of sex and gender-based medicine need to be embedded into existing curriculum, with an emphasis on clinically relevant information.ConclusionsAlthough this study represents only one medical school in the United States, information regarding sex and gender aspects of medicine is not consistently included in this curriculum without an explicit directive. These results can provide guidance for curriculum improvement to train future physicians.     

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.     

Learning cell biology as a team: a project-based approach to upper-division cell biology

To help students develop successful strategies for learning how to learn and communicate complex information in cell biology, we developed a quarter-long cell biology class based on team projects. Each team researches a particular human disease and presents information about the cellular structure or process affected by the disease, the cellular and molecular biology of the disease, and recent research focused on understanding the cellular mechanisms of the disease process. To support effective teamwork and to help students develop collaboration skills useful for their future careers, we provide training in working in small groups. A final poster presentation, held in a public forum, summarizes what students have learned throughout the quarter. Although student satisfaction with the course is similar to that of standard lecture-based classes, a project-based class offers unique benefits to both the student and the instructor.     

Literature sources for primary environmental science teachers

With school days seemingly getting shorter and packed with more and more obligations, teachers integrate core subjects like science and reading in the hopes of delivering a curriculum that is meaningful and content rich. Using trade books, primary teachers can develop and deliver science content designed to introduce students to proenvironmental behaviors built around the Next Generation Science Earth and Human Activity Standard, Human Impacts on Earth Systems, ESS3-C. The Next Generation Science standards call for integrating literacy skills and science to develop knowledge of scientific topics. This article shares ideas on how primary teachers can use a variety of children’s literature as a foundation to inspire young students to take small steps toward developing proenvironmental behaviors. Under an umbrella of three environmental themes, proenvironmental behavior, trash, and water pollution, the article describes key concepts, vocabulary, and activities designed to develop a mindfulness of proenvironmental behaviors for each selected text. While texts and learning experiences are intentionally focused on young learners (Kindergarten/first grade), they can be adapted and used in all primary grades.     

Make biology relevant again! Pre-service teachers’ views on the relevance of biology education

ABSTRACT

Biology education should be relevant to young students so that they can become interested in biology and understand biological topics in their everyday and vocational lives. We conducted interviews and collected mind maps to examine Finnish pre-service biology teachers’ (N = 16) views on the relevance of biology education. Furthermore, we analysed Finnish secondary school biology curricula, which were compared with the pre-service teachers’ answers. We classified the views on relevance into nine main categories using grounded theory as the methodological frame of reference. Pre-service teachers emphasised the relevance of biology to the student’s own life, whereas scientific practices and the nature of science were expressed in secondary school curricula more often. Novice pre-service teachers put more value on general knowledge, while more experienced pre-service teachers were more likely to mention sustainable futures and societal aspects in their reasoning. Based on the results, we identified two stages in the development of the views. This study suggests that pedagogical studies, teaching experience and teacher training have an impact on the pre-service teachers’ views about the relevance of biology education. Moreover, we could find differences between curricula and pre-service teachers’ views, especially regarding scientific practices and the role of the nature of science in biology education.     

Investigations of protein structure and function using the scientific literature: an assignment for an undergraduate cell physiology course

Undergraduate biology curricula are being modified to model and teach the activities of scientists better. The assignment described here, one that investigates protein structure and function, was designed for use in a sophomore-level cell physiology course at Earlham College. Students work in small groups to read and present in poster format on the content of a single research article reporting on the structure and/or function of a protein. Goals of the assignment include highlighting the interdependence of protein structure and function; asking students to review, integrate, and apply previously acquired knowledge; and helping students see protein structure/function in a context larger than cell physiology. The assignment also is designed to build skills in reading scientific literature, oral and written communication, and collaboration among peers. Assessment of student perceptions of the assignment in two separate offerings indicates that the project successfully achieves these goals. Data specifically show that students relied heavily on their peers to understand their article. The assignment was also shown to require students to read articles more carefully than previously. In addition, the data suggest that the assignment could be modified and used successfully in other courses and at other institutions.     

Teaching Synthetic Biology, Bioinformatics and Engineering to Undergraduates: The Interdisciplinary Build-a-Genome Course

A major challenge in undergraduate life science curricula is the continual evaluation and development of courses that reflect the constantly shifting face of contemporary biological research. Synthetic biology offers an excellent framework within which students may participate in cutting-edge interdisciplinary research and is therefore an attractive addition to the undergraduate biology curriculum. This new discipline offers the promise of a deeper understanding of gene function, gene order, and chromosome structure through the de novo synthesis of genetic information, much as synthetic approaches informed organic chemistry. While considerable progress has been achieved in the synthesis of entire viral and prokaryotic genomes, fabrication of eukaryotic genomes requires synthesis on a scale that is orders of magnitude higher. These high-throughput but labor-intensive projects serve as an ideal way to introduce undergraduates to hands-on synthetic biology research. We are pursuing synthesis of Saccharomyces cerevisiae chromosomes in an undergraduate laboratory setting, the Build-a-Genome course, thereby exposing students to the engineering of biology on a genomewide scale while focusing on a limited region of the genome. A synthetic chromosome III sequence was designed, ordered from commercial suppliers in the form of oligonucleotides, and subsequently assembled by students into ~750-bp fragments. Once trained in assembly of such DNA “building blocks” by PCR, the students accomplish high-yield gene synthesis, becoming not only technically proficient but also constructively critical and capable of adapting their protocols as independent researchers. Regular “lab meeting” sessions help prepare them for future roles in laboratory science.     

Gas Law for the Classroom

The author provides information on how science teachers can write science literacy objectives that help English language learners (ELLs) develop the scientific literacy needed for academic success in the science classroom. The article offers suggestions on how teachers can determine the vocabulary, language functions, and sentence structures that their students need to engage in critical thinking in science. An approach for collaboration with students' English as a second language (ESL) teacher is discussed.     

Information literacy in biology education: an example from an advanced cell biology course

Information literacy skills are critically important for the undergraduate biology student. The ability to find, understand, evaluate, and use information, whether from the scientific literature or from Web resources, is essential for a good understanding of a topic and for the conduct of research. A project in which students receive information literacy instruction and then proceed to select, update, and write about a current research topic in an upper-level cell biology course is described. Students research the chosen topic using paper and electronic resources, generate a list of relevant articles, prepare abstracts based on papers read, and, finally, prepare a "state-of-the-art" paper on the topic. This approach, which extends over most of one semester, has resulted in a number of well-researched and well-written papers that incorporate some of the latest research in cell biology. The steps in this project have also led to students who are prepared to address future projects on new and complex topics. The project is part of an undergraduate course in cell biology, but parts of the assignments can be modified to fit a variety of subject areas and levels.     

A case for project based learning to enact semantic waves: towards cumulative knowledge building

ABSTRACT

First-year undergraduate curricula and their delivery should assist students in the transition from previous learning experiences to learning in higher education. However, the so-called articulation gap or discontinuity between secondary and higher education has been identified as a key structural curriculum problem for first-year success in South Africa and abroad. Valuable insights into this problem came from a recent study that drew on Legitimation Code Theory (LCT). Findings revealed an unexpectedly wide gap between the high school and the university biology curricula. The high school biology curriculum displays minimal movement between context-dependent, simpler meaning and relatively decontextualized, condensed meaning common in first-year biology. LCT Semantics was also found to be a valuable tool for restructuring curricula and pedagogy to intentionally enact semantic movement and thereby a more gradual transition for students from high school to university. This paper reports on an integrative first-year biology project aimed intentionally at taking students’ concept knowledge through a wide contextual range, and repeatedly between less and more complex meaning. I reflect on how the project design steers students towards creating semantic movement during their presentations, thereby contributing to cumulative knowledge building and a more gradual transition towards first-year epistemological access.