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1.
Tom Kubala 《Community College Journal of Research & Practice》2013,37(5):331-339
This article details the experiences of a university professor and former community college president in teaching World Wide Web based graduate courses to faculty members from Florida's community colleges. These courses have provided faculty members from various parts of the state access to advanced educational opportunities. Courses have been particularly relevant to the day-to-day activities of full-time and adjunct teaching faculty members. For those who might be interested in converting traditional courses for Web-based delivery, tips are included on designing course materials and using technical experts. Emphasis is placed on the needs of the learner to maximize the benefits of this type of distance education. The 12 canons for distance learners, which served as guideposts, as community college faculty member-students progressed through the courses are included. Discussion of various course material components provides insight into the need for thoroughness in overall course design. Course evaluation results, which highlight the appreciation of community college faculty member-students for the way in which the courses were conducted, are included. For example, convenience and exibility were ranked highly as positive reasons for taking Web-based courses. Problem areas are also identified. Teaching graduate courses on the Internet to community college personnel has become an important endeavor in Florida. The University of Central Florida has made a commitment to expand the number and types of courses offered in this manner to address the needs of all students. These courses are particularly important to community college faculty members and administrators who may be precluded from taking relevant graduate courses because of geographical or time limitations. Hence, through the magic of the Internet, courses are available at their fingertips. 相似文献
2.
Deborah L. Floyd Berta Vigil Laden 《Community College Journal of Research & Practice》2013,37(11):913-932
University graduate-level programs are striving to address needs for community college leaders. One way they are doing this is by strengthening their graduate programs with relevant community college courses. Increasingly, however, community college presidents are being invited to join universities in professorial roles. These new graduate faculty leaders are bringing valuable transferable skills and experiences, but they are also experiencing transitional challenges. Studies have been conducted about other university executive administrators transitioning to university professor roles, but no studies have been conducted about community college presidents making this transition. This article represents an initial effort to explore a distinct class of leaders within academe—community college presidents-turned-professor. The findings of this exploratory study of 12 former community college presidents who transitioned to graduate university professors are reported along with stories, lessons learned, and advice for successfully crossing over from the community college sector to the university one. 相似文献
3.
Gregory Goins Mingxiang Chen Catherine White Dominic Clemence Thomas Redd Vinaya Kelkar 《CBE life sciences education》2010,9(3):241-247
At North Carolina A&T State University (NCATSU), there was a critical need to better coordinate genuine research and classroom experiences for undergraduates early in their academic career. We describe the development and implementation of a faculty alliance across academic departments to increase biomathematics research opportunities for underrepresented minorities. Our faculty alliance is called the Integrative Biomathematical Learning and Empowerment Network for Diversity (iBLEND). The fundamental purpose of the iBLEND alliance was to inspire underrepresented minorities to pursue research careers by increasing the visibility of research conducted at the interface of mathematics and biology at NCATSU. Because of the many positive impacts, iBLEND gained significant buy-in from administration, faculty, and students by 1) working from the ground up with administration to promote campus-wide biomathematics research and training, 2) fostering associations between research and regular undergraduate academic courses, 3) creating and disseminating biomathematics teaching and learning modules, and 4) enhancing learning community support at the interface of mathematics and biology. Currently, iBLEND is viewed as a productive site for graduate schools to recruit underrepresented minority students having specific competencies related to mathematical biology. 相似文献
4.
Charlene D’Avanzo 《CBE life sciences education》2013,12(3):373-382
The scale and importance of Vision and Change in Undergraduate Biology Education: A Call to Action challenges us to ask fundamental questions about widespread transformation of college biology instruction. I propose that we have clarified the “vision” but lack research-based models and evidence needed to guide the “change.” To support this claim, I focus on several key topics, including evidence about effective use of active-teaching pedagogy by typical faculty and whether certain programs improve students’ understanding of the Vision and Change core concepts. Program evaluation is especially problematic. While current education research and theory should inform evaluation, several prominent biology faculty–development programs continue to rely on self-reporting by faculty and students. Science, technology, engineering, and mathematics (STEM) faculty-development overviews can guide program design. Such studies highlight viewing faculty members as collaborators, embedding rewards faculty value, and characteristics of effective faculty-development learning communities. A recent National Research Council report on discipline-based STEM education research emphasizes the need for long-term faculty development and deep conceptual change in teaching and learning as the basis for genuine transformation of college instruction. Despite the progress evident in Vision and Change, forward momentum will likely be limited, because we lack evidence-based, reliable models for actually realizing the desired “change.”
All members of the biology academic community should be committed to creating, using, assessing, and disseminating effective practices in teaching and learning and in building a true community of scholars. (American Association for the Advancement of Science [AAAS], 2011 , p. 49)Realizing the “vision” in Vision and Change in Undergraduate Biology Education (Vision and Change; AAAS, 2011 ) is an enormous undertaking for the biology education community, and the scale and critical importance of this challenge prompts us to ask fundamental questions about widespread transformation of college biology teaching and learning. For example, Vision and Change reflects the consensus that active teaching enhances the learning of biology. However, what is known about widespread application of effective active-teaching pedagogy and how it may differ across institutional and classroom settings or with the depth of pedagogical understanding a biology faculty member may have? More broadly, what is the research base concerning higher education biology faculty–development programs, especially designs that lead to real change in classroom teaching? Has the develop-and-disseminate approach favored by the National Science Foundation''s (NSF) Division of Undergraduate Education (Dancy and Henderson, 2007 ) been generally effective? Can we directly apply outcomes from faculty-development programs in other science, technology, engineering, and mathematics (STEM) disciplines or is teaching college biology unique in important ways? In other words, if we intend to use Vision and Change as the basis for widespread transformation of biology instruction, is there a good deal of scholarly literature about how to help faculty make the endorsed changes or is this research base lacking?In the context of Vision and Change, in this essay I focus on a few key topics relevant to broad-scale faculty development, highlighting the extent and quality of the research base for it. My intention is to reveal numerous issues that may well inhibit forward momentum toward real transformation of college-level biology teaching and learning. Some are quite fundamental, such as ongoing dependence on less reliable assessment approaches for professional-development programs and mixed success of active-learning pedagogy by broad populations of biology faculty. I also offer specific suggestions to improve and build on identified issues.At the center of my inquiry is the faculty member. Following the definition used by the Professional and Organizational Development Network in Higher Education (www.podnetwork.org), I use “faculty development” to indicate programs that emphasize the individual faculty member as teacher (e.g., his or her skill in the classroom), scholar/professional (publishing, college/university service), and person (time constraints, self-confidence). Of course, faculty members work within particular departments and institutions, and these environments are clearly critical as well (Stark et al., 2002 ). Consequently, in addition to focusing on the individual, faculty-development programs may also consider organizational structure (such as administrators and criteria for reappointment and tenure) and instructional development (the overall curriculum, who teaches particular courses). In fact, Diamond (2002) emphasizes that the three areas of effort (individual, organizational, instructional) should complement one another in faculty-development programs. The scope of the numerous factors impacting higher education biology instruction is a realistic reminder about the complexity and challenge of the second half of the Vision and Change endeavor.This essay is organized around specific topics meant to be representative and to illustrate the state of the art of widespread (beyond a limited number of courses and institutions) professional development for biology faculty. The first two sections focus on active teaching and biology students’ conceptual understanding, respectively. The third section concerns important elements that have been identified as critical for effective STEM faculty-development programs. 相似文献
5.
Criminal justice programs are seeing an increase in the number of online classes both at the graduate and undergraduate levels. At the graduate level, criminal justice online education requires students to achieve mastery of higher ordered thinking and advanced analytic skills. Some students may believe that online education is simply a matter of reading postings and writing simple responses to queries. In order to counter the view that modern online courses, particularly those at the graduate level, are not academic enough, online graduate faculty must find ways to engage students through useful course design and meaningful assessments that promote deep learning. Such engagement requires faculty and students to show reflection in design as well as the integration and application of course materials in a consistent and significant way. This paper will discuss our attempts to reframe graduate criminal justice online classes in order to enhance student engagement and, ultimately, their deeper learning. 相似文献
6.
Marbach-Ad G Briken V Frauwirth K Gao LY Hutcheson SW Joseph SW Mosser D Parent B Shields P Song W Stein DC Swanson K Thompson KV Yuan R Smith AC 《CBE life sciences education》2007,6(2):155-162
As research faculty with expertise in the area of host–pathogen interactions (HPI), we used a research group model to effect our professional development as scientific educators. We have established a working hypothesis: The implementation of a curriculum that forms bridges between our seven HPI courses allows our students to achieve deep and meaningful learning of HPI concepts. Working collaboratively, we identified common learning goals, and we chose two microorganisms to serve as anchors for student learning. We instituted variations of published active-learning methods to engage students in research-oriented learning. In parallel, we are developing an assessment tool. The value of this work is in the development of a teaching model that successfully allowed faculty who already work collaboratively in the research area of HPI to apply a “research group approach” to further scientific teaching initiatives at a research university. We achieved results that could not be accomplished by even the most dedicated instructor working in isolation. 相似文献
7.
《CBE life sciences education》2014,13(4):711-723
In their 2012 report, the President''s Council of Advisors on Science and Technology advocated “replacing standard science laboratory courses with discovery-based research courses”—a challenging proposition that presents practical and pedagogical difficulties. In this paper, we describe our collective experiences working with the Genomics Education Partnership, a nationwide faculty consortium that aims to provide undergraduates with a research experience in genomics through a scheduled course (a classroom-based undergraduate research experience, or CURE). We examine the common barriers encountered in implementing a CURE, program elements of most value to faculty, ways in which a shared core support system can help, and the incentives for and rewards of establishing a CURE on our diverse campuses. While some of the barriers and rewards are specific to a research project utilizing a genomics approach, other lessons learned should be broadly applicable. We find that a central system that supports a shared investigation can mitigate some shortfalls in campus infrastructure (such as time for new curriculum development, availability of IT services) and provides collegial support for change. Our findings should be useful for designing similar supportive programs to facilitate change in the way we teach science for undergraduates. 相似文献
8.
Zachary Batz Brian J. Olsen Jonathan Dumont Farahad Dastoor Michelle K. Smith 《CBE life sciences education》2015,14(2)
The high attrition rate among science, technology, engineering, and mathematics (STEM) majors has long been an area of concern for institutions and educational researchers. The transition from introductory to advanced courses has been identified as a particularly “leaky” point along the STEM pipeline, and students who struggle early in an introductory STEM course are predominantly at risk. Peer-tutoring programs offered to all students in a course have been widely found to help STEM students during this critical transition, but hiring a sufficient number of tutors may not be an option for some institutions. As an alternative, this study examines the viability of an optional peer-tutoring program offered to students who are struggling in a large-enrollment, introductory biology course. Struggling students who regularly attended peer tutoring increased exam performance, expert-like perceptions of biology, and course persistence relative to their struggling peers who were not attending the peer-tutoring sessions. The results of this study provide information to instructors who want to design targeted academic assistance for students who are struggling in introductory courses. 相似文献
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10.
Funded by innovative programs at the National Science Foundation and the Howard Hughes Medical Institute, University of Richmond faculty in biology, chemistry, mathematics, physics, and computer science teamed up to offer first- and second-year students the opportunity to contribute to vibrant, interdisciplinary research projects. The result was not only good science but also good science that motivated and informed course development. Here, we describe four recent undergraduate research projects involving students and faculty in biology, physics, mathematics, and computer science and how each contributed in significant ways to the conception and implementation of our new Integrated Quantitative Science course, a course for first-year students that integrates the material in the first course of the major in each of biology, chemistry, mathematics, computer science, and physics. 相似文献
11.
AbstractWe describe a successful collaboration between mathematics and psychological science faculty members to create a learning community for our students that linked sections of introductory mathematical reasoning and psychological science courses. The students in our learning community were in their second or third semester. The learning community is designed so that, throughout the semester, students regularly move across the border between the two linked disciplines by completing common assignments, including a group project. We modified our existing course topics and frameworks to be intentional about building connections between the courses. 相似文献
12.
With rapid advances in biotechnology and molecular biology, instructors are challenged to not only provide undergraduate students with hands-on experiences in these disciplines but also to engage them in the “real-world” scientific process. Two common topics covered in biotechnology or molecular biology courses are gene-cloning and bioinformatics, but to provide students with a continuous laboratory-based research experience in these techniques is difficult. To meet these challenges, we have partnered with Bio-Rad Laboratories in the development of the “Cloning and Sequencing Explorer Series,” which combines wet-lab experiences (e.g., DNA extraction, polymerase chain reaction, ligation, transformation, and restriction digestion) with bioinformatics analysis (e.g., evaluation of DNA sequence quality, sequence editing, Basic Local Alignment Search Tool searches, contig construction, intron identification, and six-frame translation) to produce a sequence publishable in the National Center for Biotechnology Information GenBank. This 6- to 8-wk project-based exercise focuses on a pivotal gene of glycolysis (glyceraldehyde-3-phosphate dehydrogenase), in which students isolate, sequence, and characterize the gene from a plant species or cultivar not yet published in GenBank. Student achievement was evaluated using pre-, mid-, and final-test assessments, as well as with a survey to assess student perceptions. Student confidence with basic laboratory techniques and knowledge of bioinformatics tools were significantly increased upon completion of this hands-on exercise. 相似文献
13.
Ronald G. Sultana 《欧洲师范教育杂志》1995,18(2-3):215-229
This article presents one approach to the development of initial teacher education programmes that are based on a vision, premissed on values shared consensually by faculty staff and students. The article first provides a brief historical background of the Faculty of Education at the University of Malta, where this values‐based approach was attempted. It addresses some of the key problems faced in the development of a coherent and organic course of studies with students following graduate and post‐graduate courses, and gives an account of the way some of these problems were addressed. It is claimed that the approach adopted at the University of Malta can help other teacher educators in clarifying objectives as they set out to create coherent programmes that provide a sense of mission based on identifiable values and principles. 相似文献
14.
The Biology Intensive Orientation for Students (BIOS) Program was designed to assess the impact of a 5-d intensive prefreshman program on success and retention of biological science majors at Louisiana State University. The 2005 pilot program combined content lectures and examinations for BIOL 1201, Introductory Biology for Science Majors, as well as learning styles assessments and informational sessions to provide the students with a preview of the requirements of biology and the pace of college. Students were tracked after their BIOS participation, and their progress was compared with a control group composed of students on the BIOS waiting list and a group of BIOL 1201 students who were identified as the academic matches to the BIOS participants (high school GPA, ACT score, and gender). The BIOS participants performed significantly better on the first and second exams, they had a higher course average, and they had a higher final grade than the control group. These students also had higher success rates (grade of “A,” “B,” or “C”) during both the fall and spring semesters and remained on track through the first semester of their sophomore year to graduate in 4 yr at a significantly higher rate than the control group. 相似文献
15.
Melanie A. Robinson Jean-François Soublière Marine Agogué Denis A. Grégoire Tuvana Rua Yves Plourde 《Decision Sciences Journal of Innovative Education》2023,21(3):167-176
Most graduate programs in management require students to carry out a substantive research project. However, few management students have a comfortable command of the statistical techniques needed to realize such quantitative projects. This can lead to student anxiety and stress, which challenges instructors to devise ways to build students’ self-efficacy with statistical analysis. Drawing on game-based learning principles, we developed an exercise to help students in a graduate-level research methods course practice these statistical techniques. Designed around a series of four gamified challenges, students perform basic statistical analyses (correlations, t-tests, and simple linear regression) to solve puzzles and unlock a reward hidden in a mysterious red envelope. We used the exercise on seven occasions (five times in the methods course and twice in a graduate program preparatory course). After launching it in fall 2021, we observed that students were engaged and enthusiastic about the exercise. To ascertain its effectiveness more systematically, we collected data in five subsequent sections using a pretest/posttest design (N = 84) which showed that perceptions of statistics self-efficacy increased following the exercise. We conclude by suggesting that our exercise can be tailored to other learning contexts such as management and statistics-centered courses. 相似文献
16.
Biological engineering will be important for the future application of advances in biology to solve problems facing humankind. The philosophical foundation for broad undergraduate biological engineering programmes has previously been given, but biological engineering graduate programmes, where specialization normally occurs, have remained undefined. While specialization will continue in these graduate programmes, efforts must be made to relate research and teaching results to: (1) the analogical systems approach; and (2) the derivation of biological information to produce new general engineering techniques. Finally, a set of graduate-level core courses is suggested. 相似文献
17.
Anastasia P. Samaras Toya Jones Frank Monique Apollon Williams Emily Christopher William Harry Rodick III 《Studying Teacher Education》2016,12(2):170-187
Student feedback collected through program evaluation of secondary education licensure and Master’s program clinical experiences prompted us to conduct a collective self-study. We used a reflective framework for analysis and discussion of the shifts students in our courses made as they progressed from observers to practicing teachers. Along with our graduate students, we collected and shared data and analysis from two courses – an introductory mathematics course for pre-service teachers and a capstone self-study teacher research course for in-service teachers. Data included students’ reflective accounts of their clinical experiences, dialogue with peers in response memos and focus groups, and our meta-conversation about and interpretations of data captured in meeting notes, audio recordings of meetings, email exchanges, and video conferencing over a two-month period. Analysis resulted in reframed thinking about our teaching and implications for program coherence, including provision of meaningful participant observations in diverse settings, design of dialogic platforms for students to make connections, and support of a critical level of reflection to inform teacher professional practice. The results are informative to teacher educators and programs seeking to better understand their roles in designing dialogic spaces for students to think deeply about the connections of their courses to clinical experiences and in supporting ongoing teacher professional development. The study highlights the benefits of faculty collective self-studies and contributes to the literature on self-study for program development. 相似文献
18.
The utilization of biology research resources, coupled with a “learning by inquiry” approach, has great potential to aid students in gaining an understanding of fundamental biological principles. To help realize this potential, we have developed a Web portal for undergraduate biology education, WormClassroom.org, based on current research resources of a model research organism, Caenorhabditis elegans. This portal is intended to serve as a resource gateway for students to learn biological concepts using C. elegans research material. The driving forces behind the WormClassroom website were the strengths of C. elegans as a teaching organism, getting researchers and educators to work together to develop instructional materials, and the 3 P's (problem posing, problem solving, and peer persuasion) approach for inquiry learning. Iterative assessment is an important aspect of the WormClassroom site development because it not only ensures that content is up-to-date and accurate, but also verifies that it does, in fact, aid student learning. A primary assessment was performed to refine the WormClassroom website utilizing undergraduate biology students and nonstudent experts such as C. elegans researchers; results and comments were used for site improvement. We are actively encouraging continued resource contributions from the C. elegans research and education community for the further development of WormClassroom. 相似文献
19.
Introductory Biology Courses: A Framework To Support Active Learning in Large Enrollment Introductory Science Courses 总被引:1,自引:0,他引:1 
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下载免费PDF全文 Ann C. Smith Richard Stewart Patricia Shields Jennifer Hayes-Klosteridis Paulette Robinson Robert Yuan 《CBE life sciences education》2005,4(2):143-156
Active learning and research-oriented activities have been increasingly used in smaller, specialized science courses. Application of this type of scientific teaching to large enrollment introductory courses has been, however, a major challenge. The general microbiology lecture/laboratory course described has been designed to incorporate published active-learning methods. Three major case studies are used as platforms for active learning. Themes from case studies are integrated into lectures and laboratory experiments, and in class and online discussions and assignments. Students are stimulated to apply facts to problem-solving and to learn research skills such as data analysis, writing, and working in teams. This course is feasible only because of its organizational framework that makes use of teaching teams (made up of faculty, graduate assistants, and undergraduate assistants) and Web-based technology. Technology is a mode of communication, but also a system of course management. The relevance of this model to other biology courses led to assessment and evaluation, including an analysis of student responses to the new course, class performance, a university course evaluation, and retention of course learning. The results are indicative of an increase in student engagement in research-oriented activities and an appreciation of real-world context by students. 相似文献
20.
Steven W. Rissing 《CBE life sciences education》2013,12(3):429-440
Most American colleges and universities offer gateway biology courses to meet the needs of three undergraduate audiences: biology and related science majors, many of whom will become biomedical researchers; premedical students meeting medical school requirements and preparing for the Medical College Admissions Test (MCAT); and students completing general education (GE) graduation requirements. Biology textbooks for these three audiences present a topic scope and sequence that correlates with the topic scope and importance ratings of the biology content specifications for the MCAT regardless of the intended audience. Texts for “nonmajors,” GE courses appear derived directly from their publisher''s majors text. Topic scope and sequence of GE texts reflect those of “their” majors text and, indirectly, the MCAT. MCAT term density of GE texts equals or exceeds that of their corresponding majors text. Most American universities require a GE curriculum to promote a core level of academic understanding among their graduates. This includes civic scientific literacy, recognized as an essential competence for the development of public policies in an increasingly scientific and technological world. Deriving GE biology and related science texts from majors texts designed to meet very different learning objectives may defeat the scientific literacy goals of most schools’ GE curricula. 相似文献