Four decades of teaching developmental biology in Germany

I have taught developmental biology in Essen for 30 years. Since my department is named Zoophysiologie (Zoophysiology), besides Developmental Biology, I also have to teach General Animal Physiology. This explains why the time for teaching developmental biology is restricted to a lecture course, a laboratory course and several seminar courses. However, I also try to demonstrate in the lecture courses on General Physiology the close relationship between developmental biology, physiology, morphology, anatomy, teratology, carcinogenesis, evolution and ecology (importance of environmental factors on embryogenesis). Students are informed that developmental biology is a core discipline of biology. In the last decade, knowledge about molecular mechanisms in different organisms has exponentially increased. The students are trained to understand the close relationship between conserved gene structure, gene function and signaling pathways, in addition to or as an extension of, classical concepts. Public reports about the human genome project and stem cell research (especially therapeutic and reproductive cloning) have shown that developmental biology, both in traditional view and at the molecular level, is essential for the understanding of these complex topics and for serious and non-emotional debate.     

Problem-based learning within endocrine physiology lectures

Methods were needed to improve the interest of medical students in the 10-lecture Endocrine Physiology block at the end of the second semester of study. Other incentives for improvement included the possibility of attracting students into endocrine research electives and the pressure to improve teaching approaches that results from the high tuition they pay. The principal approach adopted was that of whole class problem-based learning sessions (PBLS) in which the lecture period begins with a brief overview of one to three simplified cases, followed by the usual didactic lecture. At the end of the lecture, each PBL case is read in detail, with several questions posed to the students. Their answers are then used to reinforce concepts from the lecture material. This method can also provide some continuity between lectures, either by using a case in several lectures to illustrate different points, or by posing a question at the beginning of class that illustrates a point from the prior lecture. The outcome of this approach has been very successful: student evaluations of the lecture block and their attendance have significantly improved.     

A Biochemistry of Human Disease course for undergraduate and graduate students

This paper describes the experience of members of a medical school faculty who have been offering for more than 10 years a two-course series in the biochemistry of human disease to undergraduate students majoring in biochemistry, biology, or chemistry. Each of the two 3-credit courses meets twice a week for 90 min per session. The courses are divided into five three-week blocs (total number of sessions per bloc, six), each of which is taught by a different instructor. The sixth and last class in each of the blocs is devoted to an exam; there is no cumulative final exam. The topics that are covered include the following: diabetes mellitus, alcoholism, Alzheimer's disease, trophoblastic diseases of pregnancy, molecular and cellular mechanisms of cancer (including chemical carcinogenesis), disorders of calcium metabolism, biochemical and nutritional causes of anemia, collagen diseases, and gene replacement therapy. The various teaching formats and kinds of reading assignments that are used are discussed, as are the reactions of selected faculty who have participated in these courses. The positive experience we have had with a bloc approach to topics-based, multi-instructor courses in human disease should encourage basic science faculty at other medical schools in the US and elsewhere to become involved in teaching specialized, advanced courses to undergraduate, pre-professional students.     

酶工程课程教学改革探索

"酶工程"是生物工程专业的主干课程,其主要内容是研究酶的生产和应用。结合课程教学实践,从认真选择教材、优化教学内容,改进教学方法和手段,完善考核形式等方面对"酶工程"课程教学进行了初步探讨,以期提高教学效果。     

浅谈PBL+CBL的教学方法在临床生物化学检验技术教学中的应用

临床生物化学检验技术是医学检验专业学生的必修课之一,是一门实践性和应用性非常强的课程。然而单一的传统教学模式已经不能满足国家应用型人才培养的需求,本文探讨了"问题"结合"案例"的教学方法(PBL+CBL)在临床生物化学检验技术教学中的应用,为培养高素质的医学检验人才提供了教育思路。     

Introductory biology courses: a framework to support active learning in large enrollment introductory science courses

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.     

“食品微生物学”课程以问题为基础的学习与小规模限制性在线课程融合教学模式探索

工科专业基础课程教学模式改革对于工程教育专业认证和应用型人才培养至关重要。以工程教育专业认证为契机,针对互联网背景下传统教学模式的不足,基于"食品微生物学"课程理论性和实践性强的特点,采用以问题为基础的学习(Problem-Based Learning,PBL)与小规模限制性在线课程(Small Private Online Course,SPOC)融合教学模式,并对该教学模式的课前问题导入、课中问题介入和课后问题反馈实施过程以及实践成果进行了分析探讨,以期提高学生自主学习能力和团队协作意识,为工程教育专业认证和应用型地方本科院校工科专业基础课程教学的开展提供借鉴。     

Endocrine physiology in a patient-centered learning curriculum

The medical curriculum at the University of North Dakota School of Medicine and Health Sciences has recently been redesigned into a problem-based/traditional hybrid model that utilizes an integrated organ systems-based approach to teach basic and clinical sciences. The number of lecture hours in general has been greatly reduced, and, in particular, lecture hours in physiology have been reduced by 65%. Students learn basic science in small groups led by a faculty facilitator, and students are responsible for a great deal of their own teaching and learning. The curriculum is centered around patient cases and is called patient-centered learning (PCL). The curriculum includes traditional lectures and laboratories supporting faculty-generated learning objectives. Endocrine physiology is taught in year one, utilizing four weeks of patient cases that emphasize normal structure and function of endocrine systems. Endocrine physiology is revisited in year two, which is primarily focused on pathobiology. The PCL curriculum, with emphasis on the endocrine component, is described in detail along with key portions of an endocrine case.     

A novel approach to physiology education for biomedical engineering students

It is challenging for biomedical engineering programs to incorporate an indepth study of the systemic interdependence of cells, tissues, and organs into the rigorous mathematical curriculum that is the cornerstone of engineering education. To be sure, many biomedical engineering programs require their students to enroll in anatomy and physiology courses. Often, however, these courses tend to provide bulk information with only a modicum of live tissue experimentation. In the Electrical, Computer, and Biomedical Engineering Department of the University of Rhode Island, this issue is addressed to some extent by implementing an experiential physiology laboratory that addresses research in electrophysiology and biomechanics. The two-semester project-based course exposes the students to laboratory skills in dissection, instrumentation, and physiological measurements. In a novel approach to laboratory intensive learning, the course meets on six Sundays throughout the semester for an 8-h laboratory period. At the end of the course, students are required to prepare a two-page conference paper and submit the results to the Northeast Bioengineering Conference (NEBC) for consideration. Students then travel to the conference location to present their work. Since the inception of the course in the fall of 2003, we have collectively submitted 22 papers to the NEBC. This article will discuss the nature of the experimentation, the types of experiments performed, the goals of the course, and the metrics used to determine the success of the students and the research.     

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.     

Combination of didactic lectures and case-oriented problem-solving tutorials toward better learning: perceptions of students from a conventional medical curriculum

The Department of Physiology of Pramukhswami Medical College at Anand, Gujarat, India, started using problem-based learning in a modified way along with didactic lectures to improve students' understanding and motivate them toward self-directed study. After the didactic lectures were taken for a particular system, clearly defined short clinical problems related to that system were given to the students in the tutorial classes. Each tutor was assigned three to four groups of five to six students each. Problems were accompanied with relevant questions so as to streamline the thought processes of the first-year undergraduates. The tutor then facilitated the study process, and the students discussed among themselves to derive their solutions. At the end of the sessions, feedback was taken from the students through a planned questionnaire on a three-point scale. Of a total of 278 students over a span of 3 yr from 1999 to 2002, 74.4% of students favored a judicious mixture of didactic lectures and case-oriented problem solving in tutorial classes to be an efficient modality in understanding a system under study, and 84% of students stated the mixture of didactic lectures and case-oriented problem solving to be beneficial in relating a clinical condition to the basic mechanism; 82% of students believed that this module helped with better interactions among their batch mates, and 77.2% of students hoped to perform better in the university examination due to this new teaching/learning modality. They also expressed that this gave them ample motivation to do self-directed learning. It may therefore be concluded from the results of the present study that it is possible to have a problem-based learning module in the form of case-oriented problem-solving tutorials coexistent with the traditional didactic lecture module in the first year of medical education under a conventional curriculum.     

Bioinformatics Goes to School—New Avenues for Teaching Contemporary Biology

Since 2010, the European Molecular Biology Laboratory''s (EMBL) Heidelberg laboratory and the European Bioinformatics Institute (EMBL-EBI) have jointly run bioinformatics training courses developed specifically for secondary school science teachers within Europe and EMBL member states. These courses focus on introducing bioinformatics, databases, and data-intensive biology, allowing participants to explore resources and providing classroom-ready materials to support them in sharing this new knowledge with their students.In this article, we chart our progress made in creating and running three bioinformatics training courses, including how the course resources are received by participants and how these, and bioinformatics in general, are subsequently used in the classroom. We assess the strengths and challenges of our approach, and share what we have learned through our interactions with European science teachers.     

Don't dump the didactic lecture; fix it

Numerous articles have been published on the merits of active learning, and collectively they present a body of compelling evidence that these methods do enhance learning. In presenting arguments for active learning, it is often suggested that the traditional didactic lecture is more passive in nature and less effective as a teaching tool. However, a well organized lecture remains one of the most effective ways to integrate and present information from multiple sources on complex topics, such as those encountered in the teaching of physiology. This article presents an argument for enhancing lectures by incorporating active learning activities within their framework, and it is noted that engagement of the student is a key element making active learning activities work. Finally, suggestions are provided on the basis of the author's experience of things instructors can do to make lecture-based courses more engaging to students and, hence, promote learning.     

Multiple-format sessions for teaching endocrine physiology

The University of Kentucky medical curriculum was revised in 1994 to implement a more interactive approach. The Endocrine Physiology section of the new physiology course, Human Function, was modified from its former daily lecture and weekly laboratory format to eight daily 3 1/2-h sessions. Each session is composed of four components: a didactic lecture, a whole class discussion session, a quiz, and a patient presentation. These components are presented in a staggered format over the course of 2 days, i.e., the lecture is presented on the first day, and the remaining three components take place on the second day. This allows students to assimilate the new lecture material before participating in the discussion session, quiz, and patient presentation, which are more interactive. This format has been received favorably by the students because of its variety, and it is easier to keep up with the material.     

Problem-based learning and the medical school: another case of the emperor's new clothes?

For almost four decades, problem-based learning (PBL) has been the stated cornerstone of learning in many medical schools. Proponents of PBL cite the open nature of the learning experience where students are free to study in depth, unencumbered by the burdens of broad courses based on the memorization of facts; detractors, on the other hand, cite the lack of breadth and factual knowledge required for professional qualification. Both points of view have merit. Professional schools have a different set of needs and requirements, and it is these that drive the curriculum and learning philosophies. The constraints of the professional school are so different from those of the purely academic environment that PBL, while admirably suited to the latter, is just problem solving in the former.     

Comparing biology majors from large lecture classes with TA-facilitated laboratories to those from small lecture classes with faculty-facilitated laboratories

The teaching faculty for this course sought to address their own concerns about the quality of student learning in an impersonal large lecture biology class for majors, the difficulties in getting to know each student by name, and difficulties in soliciting answers and reactions from the students during the lecture. Questions addressed by this study were, Do active-learning activities in a small and personal lecture setting enhance student learning more than active-learning activities in large impersonal lectures? and Are students more satisfied with an educational experience in a small and personal lecture setting? Based on faculty perceptions of how they best relate to their students, the prediction was that the students in the experimental group with small lecture classes and increased direct contact with the teaching faculty would learn physiological principles better than the students in the control group in the large impersonal lecture portion of the course. One of the laboratory sections of this large enrollment biology course was randomly selected to be taught with separate small lectures by the teaching faculty. In addition, the teaching faculty participated in the laboratory with these students during their experiments correlated with the lecture material. The students in both groups were compared by pre- and posttests of physiological principles, final course grades, and class satisfaction surveys.     

“小组学习”模式在基础医学课程中的实践应用：以医学免疫学为例

将"小组学习"模式应用于基础医学课程"医学免疫学"的教学,在理论课堂采用案例导学、问题导学、角色转换导学和专题讨论导学,实践教学过程针对课堂实验、实验选修课和大学生创新创业项目进行层次化导学。综合运用思维导图、问卷星、成长袋等多元化教学方法和手段,编写思政案例库进行专业课课程思政,结合小组过程性考核进行多元化考核评价。该模式通过培养学生自主学习能力、小组合作能力、实践能力、创新能力和人文素质,为培养高素质、高能力的应用型医学人才奠定基础。该教学模式得到了绝大多数学生的认同,可为基础医学及其他相关课程的开展及高校人才培养提供思路和参考。     

Inquiry-based laboratory course improves students' ability to design experiments and interpret data

We redesigned our intermediate-level organismal physiology laboratory course to center on student-designed experiments in plant and human physiology. Our primary goals were to improve the ability of students to design experiments and analyze data. We assessed these abilities at the beginning and end of the semester by giving students an evaluation tool consisting of an experimental scenario, data, and four questions of increasing complexity. To control for nontreatment influences, the improvement scores (final minus initial score for each question) of students taking both the laboratory and the companion lecture course were compared with those of students taking the lecture course only. The laboratory + lecture group improved more than the lecture-only group for the most challenging question. This evidence suggests that our inquiry-based curriculum is achieving its primary goals. The evaluation tool that we developed may be useful to others interested in measuring experimental analysis abilities in their students.