Teachers' journal club: bridging between the dynamics of biological discoveries and biology teachers

Since biology is one of the most dynamic research fields within the natural sciences, the gap between the accumulated knowledge in biology and the knowledge that is taught in schools, increases rapidly with time. Our long-term objective is to develop means to bridge between the dynamics of biological discoveries and the biology teachers and students. Here we report on our recent initiative towards this objective in which we established a journal club forum as a means towards the professional development of biology teachers. We used the journal club format, which is common within the scientific community, in order to engage biology teachers in a constructivist type of learning in which they acquire new skills and at the same time are continuously updated as to biological discoveries, and can then develop updated activities for their biology students. We suggest using the journal club format for the long-term professional development of biology teachers.     

The Relationship Between Scientific Knowledge and Behaviour: An HIV/AIDS Case

Debates on the role of scientific knowledge to affect behaviour are continuing. The theory of planned behaviour suggests that behaviour is influenced by attitudes, subjective norms and perceived behavioural control and not by knowledge. However, a large body of knowledge argues that increased HIV/AIDS-related knowledge leads to the adoption of safe behavioural practices. The purpose of this non-experimental survey study, therefore, was to investigate the correlation between academic HIV/AIDS knowledge, functional HIV/AIDS knowledge and self-reported behavioural preferences of 300 biology and 243 non-biology students from nine South African schools. Results suggest a correlation between students’ understanding of academic and functional HIV/AIDS knowledge. The behavioural preferences of both biology and non-biology students were generally the same and safe. Among biology students, correlation was observed between academic HIV/AIDS knowledge and self-reported safe behavioural preferences, which was not the case for non-biology students, where functional HIV/AIDS knowledge correlated with self-reported safe behavioural preferences. Within schools, however, no correlation was found between both forms of HIV/AIDS knowledge and self-reported safe behavioural preferences. There were indications that context-specific local factors have a greater influence on behavioural preferences. These findings suggest that the type of knowledge that could influence behaviour is informed by context-specific dynamics.     

Learning developmental biology has priority in the life sciences curriculum in Singapore

Singapore has embraced the life sciences as an important discipline to be emphasized in schools and universities. This is part of the nation's strategic move towards a knowledge-based economy, with the life sciences poised as a new engine for economic growth. In the life sciences, the area of developmental biology is of prime interest, since it is not just intriguing for students to know how a single cell can give rise to a complex, coordinated, functional life that is multicellular and multifaceted, but more importantly, there is much in developmental biology that can have biomedical implications. At different levels in the Singapore educational system, students are exposed to various aspects of developmental biology. The author has given many guest lectures to secondary (ages 12-16) and high school (ages 17-18) students to enthuse them about topics such as embryo cloning and stem cell biology. At the university level, some selected topics in developmental biology are part of a broader course which caters for students not majoring in the life sciences, so that they will learn to comprehend how development takes place and the significance of the knowledge and impacts of the technologies derived in the field. For students majoring in the life sciences, the subject is taught progressively in years two and three, so that students will gain specialist knowledge in developmental biology. As they learn, students are exposed to concepts, principles and mechanisms that underlie development. Different model organisms are studied to demonstrate the rapid advances in this field and to show the interconnectivity of developmental themes among living things. The course inevitably touches on life and death matters, and the social and ethical implications of recent technologies which enable scientists to manipulate life are discussed accordingly, either in class, in a discussion forum, or through essay writing.     

生物化学与分子生物学教学模式对比研究

生物化学与分子生物学是医学专业的必修基础课,独立学院学生是大学生群体中的特殊群体,提高他们学习生物化学与分子生物学的兴趣,增加考试通过率是独立学院面临的一项迫切任务.对两组共156名南通大学杏林学院临床专业学生进行了一学年的生物化学教学模式对比研究,结果表明:在对独立学院的生物化学教学中,多媒体教学和随堂测验相结合的教学模式优于仅采用多媒体教学,很有成效.     

面向中学生物教育的高师遗传学教学改革

遗传学知识,在中学生物教学中占有较大比重,随着中学新课改的实施,生物教材在教学内容上也有了一些变化。为使高师院校的遗传学教学适应中学生物教学的需要以及高师院校对师范生的培养要求,作者对遗传学教学内容进行了改革,使其与中学生物教学内容和特点紧密结合,同时在遗传学教学中渗透了对学生生物教学技能的培养。     

How fieldwork-oriented biology teachers establish formal outdoor education practices

ABSTRACT

Fieldwork is an important part of biology as well as science and biology education. However, teachers perceive several reasons for the limited use of fieldwork in schools. Further, outdoor education is often organised as a single fieldtrip guided by outdoor educators, and little research has been done on fieldwork as a regular part of formal biology education. This case study explores three secondary-school biology teachers who untypically use outdoor education as a major part of their ecology courses for 8^th grade students (median age 14). Berger and Luckmann’s theory of the process of institutionalization as a theoretical background is used to interpret the pedagogical and organizational choices of the case study teachers. Analysis of the interviews of the selected three teachers revealed pedagogical and organizational means through which outdoor teaching is institutionalized into a regular activity in biology lessons. The teachers considered regularity, assessment practices and the school curriculum as major tools to legitimate outdoor learning as a formal schoolwork and foster successful learning. However, they also emphasised students’ freedom during outdoor activities. The findings are discussed in terms of how the teachers succeeded in combining the institutional order of formal schooling with students’ freedom in nature.     

What Conceptions do Greek School Students Form about Biological Evolution?

In Greece, since 2000, the teaching of evolutionary theory is restricted solely to lower (junior) high school and specifically to ninth grade. Even though the theory of evolution is included to the 12th grade biology textbook, it is not taught in Greek upper (senior) high schools. This study presents research conducted on the conceptions of Greek students regarding issues set out in the theory of evolution after the formal completion of the teaching of the theory. The sample comprised 411 10th grade students from 12 different schools. The research results show that the students appear to have a positive view of the idea of evolution, the evolution of man, and the common origin of organisms. However, they have retained many alternative views, or else they are completely in ignorance of basic issues in evolutionary theory regarding: what is considered evolution in biology, the main mechanism of evolutionary changes in what is considered natural selection, what the theory of evolution actually explains, and what the word theory means in science. At least in Greece, these views still prevail because the theory of evolution is marginalized in the teaching of biology in Greek schools, and biology education does not help students formulate overall conceptual structures to enable them to understand the question of biological change.

Teaching biophysics. Strategies for recruiting and retaining minorities in physics and biophysics.

Several strategies directed toward increasing the participation of minority students in physics and biophysics are presented. Since the number of minority students entering college with an interest in science and mathematics must be increased if we expect to see more students graduating in science, several programs aimed at increasing the level of instruction of physics and biology in urban middle schools and high schools are outlined. We also describe approaches designed to increase the retention of science major during the freshman core physics course where many potential science majors are lost. Increasing the number of minority students at the PhD level will rely increasingly on partnerships between research universities and historically black colleges and universities (HBCUs) and several programs already in effect are given as examples of such linkages.     

A first attempt to bring computational biology into advanced high school biology classrooms

Computer science has become ubiquitous in many areas of biological research, yet most high school and even college students are unaware of this. As a result, many college biology majors graduate without adequate computational skills for contemporary fields of biology. The absence of a computational element in secondary school biology classrooms is of growing concern to the computational biology community and biology teachers who would like to acquaint their students with updated approaches in the discipline. We present a first attempt to correct this absence by introducing a computational biology element to teach genetic evolution into advanced biology classes in two local high schools. Our primary goal was to show students how computation is used in biology and why a basic understanding of computation is necessary for research in many fields of biology. This curriculum is intended to be taught by a computational biologist who has worked with a high school advanced biology teacher to adapt the unit for his/her classroom, but a motivated high school teacher comfortable with mathematics and computing may be able to teach this alone. In this paper, we present our curriculum, which takes into consideration the constraints of the required curriculum, and discuss our experiences teaching it. We describe the successes and challenges we encountered while bringing this unit to high school students, discuss how we addressed these challenges, and make suggestions for future versions of this curriculum.We believe that our curriculum can be a valuable seed for further development of computational activities aimed at high school biology students. Further, our experiences may be of value to others teaching computational biology at this level. Our curriculum can be obtained at http://ecsite.cs.colorado.edu/?page_id=149#biology or by contacting the authors.     

Stomata: Versatile Sensory Devices but Difficult Experimental Subjects

This study examined what worldviews are present among Dutch students and teachers and how the students cope with scientific knowledge acquired in the biology classroom. Furthermore, we investigated what learning and teaching strategies teachers adopt when they teach about evolution and worldviews. For this survey, 10 schools for higher general secondary education or pre-university level were selected. The data showed that most teachers did not have an articulated learning and teaching strategy. Controversial topics and discussions with students about their own worldviews were ignored in the classroom. Furthermore, the data revealed that students and teachers have a large variety of different worldviews. Some students acknowledged having difficulties coping with the knowledge gained from the classroom, because it contradicted their own worldviews. These results support our hypothesis that there is need for an explicit learning and teaching strategy that supports both teachers and students to teach and learn about evolution in multiple contexts.     

Reviewing the curriculum

The potential use of IT in secondary biology teaching is enormous, although it is a huge undertaking and fairly daunting to newcomers. Computer learning packages and the web can offer a variety of opportunities for learning, ranging from non-interactive content provision to highly interactive student-centred learning experiences. The learning materials in use in New South Wales (NSW) schools include information web sites, computer learning packages as tutorial or revision material, computer learning packages made by the students, virtual field trips, simulations, and virtual laboratories. In addition, students and teachers are using the web for communicating amongst themselves via email, newsgroups and discussion lists, videoconferencing for both local and global communications, and telecollaborative projects. This article will focus on materials used in student learning, and on the forms of electronic communication in use within the school system. A list of resources is provided.     

Evolution Education in Utah: A State Office of Education–University Partnership Focuses on Why Evolution Matters

Several groups of people are essential for effectively teaching the theory of evolution in public schools. Teachers of course are at the leading edge of educating students. However, school district administrators, school boards, state education officers, and university professors all play critical roles in this endeavor. Whereas scientific discoveries and teacher training typically occur at the university level, it is school district leaders and teachers who actually disseminate this information in a way that creates an educated population of students. In this study, we introduce a partnership focused on strengthening evolution education in Utah’s public schools. Our program centers on the importance of evolution as an applied science and one that can be readily integrated throughout the biology curriculum. Our 2-day workshop—conducted in each Utah school district—brings together elected school board members, school district administrators, public school science teachers, and university professors to overcome barriers that can arise when teaching the theory of evolution as part of the 7–12 public school curriculum.     

Misconceptions About Evolution in Brazilian Freshmen Students

Regarding such an important issue as our origin, as well as the origin of all biological diversity, it is surprising to realize that evolution still faces drawbacks in keeping its deserved notability as a unifying theory in biology. This does not happen because evolutionism lacks validity as a scientific theory, but rather because of several misconceptions regarding evolutionary biology that were and continue to be found in elementary and secondary education. Furthermore, mistaken evolutionary ideas also affect some philosophical and social issues. The aim of the present study was to evaluate knowledge about evolution among freshman students from distinct majoring areas at Universidade Estadual do Centro-Oeste do Paraná (UNICENTRO), Brazil. The research was carried out based on a ten-question questionnaire about evolution with distinct levels of difficulty, comprising the most observed misconceptions. In this study, 231 students attending classes in biological sciences (morning and evening schedule), exact sciences (agronomy, physics, chemistry, and math), and human sciences (history, geography, and pedagogy) were interviewed. The total average of right answers was 48.8%, and the highest average per course obtained was 58.7% from the students attending biological sciences (evening schedule). Although evolutionary biology and ecology are supposed to represent teaching guide issues according to the recommendations of the National Curricular Parameters for the Secondary School, the data obtained suggest that the evidence for evolution, the role of natural selection and random events, as well as the sources of variation, must be better focused at schools.     

Biochemistry,Coming Along with Melodies: Instructional Design and Teaching Tips for Introduction of Biochemistry Course

The first class of a higher education course, in most cases, is an introduction that covers the learning goals, course overview, syllabus, and evaluation mode. The effectiveness of an introduction lecture is vital for students to develop an interest in the course. Biochemistry is the foundation of a vast array of scientific disciplines; therefore, it is a core course required for medical schools and life science majors. However, many students are often intimidated by the complex, intertwined metabolic pathways composed of a great variety of structurally diverse biomolecules. Well begun is half done: a good introduction is essential for the success of a course and this is particularly true for teaching of biochemistry. As an educator with over twenty years of teaching experience in biochemistry to students of biology, medicine, pharmacy, and nursing at Peking University, I have successfully enriched the introduction class with delightful biochemistry songs, multiple sources of educational materials, and biochemistry-related knowledge in medical humanities. These strategies and tips have proven effective, and I hope it can be enlightening and helpful to the teaching of biochemistry.     

The Mathematical Basis of Mendelian Genetics

In a climate where increasing numbers of students are encouraged to pursue post-secondary education, the level of preparedness students have for college-level coursework is not far from the minds of all educators, especially high school teachers. Specifically within the biological sciences, introductory biology classes often serve as the gatekeeper or a pre-requisite for subsequent coursework in those fields and pre-professional programmes (eg pre-medicine or pre-veterinarian). Thus, how helpful high school science and mathematics experiences are in preparing students for their introductory biology classes is important and relevant for teachers, science educators and policy makers alike. This quantitative study looked at the association between students' high school science and mathematics experiences with introductory college biology performance. Using a nationally representative sample of US students (n?=?2667) enrolled in 33 introductory college biology courses, a multi-level statistical model was developed to analyse the association between high school educational experiences and the final course grade in introductory biology courses. Advanced high school science and mathematics coursework, an emphasis on a deep conceptual understanding of biology concepts and a prior knowledge of concepts addressed in well-structured laboratory investigations are all positively associated with students' achievement in introductory college biology.     

Attitudes, behaviour and knowledge on sexuality among female adolescents in Zagreb, Croatia

The aim of this study was to estimate the level of knowledge about sexuality, attitudes and sexual behaviour of female adolescents. The study included 194 female students, 117 from Medical High School (MHS) and 77 from General High School (GHS) in Zagreb. Data was collected using an anonymous self-administered questionnaire. In addition to items on personal data (age, parental education etc.), the participants were asked to define terms about sexuality (e.g. menstruation, puberty) the definitions of which are found in biology textbooks for the fifth and eighth grade of primary school. The aim of the third part of the survey was to collect information about attitudes and behaviour of female adolescents. The results showed a low level of knowledge in students of both schools. General High School students showed a higher level of knowledge than their Medical High School peers. One fifth of General High School students and 1/3 of Medical High School students were unable to define the term "menstruation". The majority of adolescents talk about sexuality with their friends, 92.1% of General High School and 81.2% of Medical High School students. Almost 50% of students of both schools would like to talk about sexuality with their school doctor. 6.9% of Medical High School students had at least one sexual intercourse while none of the General High School students had been sexually active at the time of the survey. As the majority of students were not sexually active and results showed a rather low level of knowledge, this seems to be the ideal period for the implementation of educational programs aimed at increasing the level of knowledge, and thus preventing unwanted consequences (STD, pregnancy, abortion, infertility).     

Citizen science and wildlife biology: Synergies and challenges

Citizen science (CS) has evolved over the past decades as a working method involving interested citizens in scientific research, for example by reporting observations, taking measurements or analysing data. In the past, research on animal behaviour has been benefitting from contributions of citizen scientists mainly in the field of ornithology but the full potential of CS in ecological and behavioural sciences is surely still untapped. Here, we present case studies that successfully applied CS to research projects in wildlife biology and discuss potentials and challenges experienced. Our case studies cover a broad range of opportunities: large‐scale CS projects with interactive online tools on bird song dialects, engagement of stakeholders as citizen scientists to reduce human–wildlife conflicts, involvement of students of primary and secondary schools in CS projects as well as collaboration with the media leading to successful recruitment of citizen scientists. Each case study provides a short overview of the scientific questions and how they were approached to showcase the potentials and challenges of CS in wildlife biology. Based on the experience of the case studies, we highlight how CS may support research in wildlife biology and emphasise the value of fostering communication in CS to improve recruitment of participants and to facilitate learning and mutual trust among different groups of interest (e.g., researchers, stakeholders, students). We further show how specific training for the participants may be needed to obtain reliable data. We consider CS as a suitable tool to enhance research in wildlife biology through the application of open science procedures (i.e., open access to articles and the data on publicly available repositories) to support transparency and sharing experiences.     

Designing and implementing a new advanced level biology course

Salters-Nuffield Advanced Biology is a new advanced level biology course, piloted from September 2002 in England with around 1200 students. This paper discusses the reasons for developing a new advanced biology course at this time, the philosophy of the project and how the materials are being written and the specification devised. The aim of the project is to provide an up-to-date course that interests students, is considered appropriate by teachers and other professionals in biology, and takes full advantage of modern developments in biology and in teaching.     

Differences in acquired knowledge and attitudes achieved with traditional,computer-supported and virtual laboratory biology laboratory exercises

This paper reports on the contribution to biological knowledge of three different laboratory technologies and also endeavours to discover which technology students prefer the most. To examine differences in knowledge gained and learners’ preferences for different technologies in biology laboratory work, we prepared three variants (triplets) of three laboratory exercises. Each laboratory variant in a triplet was prepared as a classical laboratory work, a computer-supported laboratory and an interactive virtual simulation. A group of 670 learners at a school for all genders, aged between 11 and 15 (6th to 9th grade) of lower secondary Slovenia schools performed three well-known and easy to perform laboratory exercises that are included in their curriculum (‘Gas Exchange’, ‘Activity of Yeast’ and ‘Heart Rate’) as a traditional, computer-supported laboratory and computer simulation. The data indicated that there were no statistical differences pertaining to students’ knowledge gain between these laboratory technologies with regard to grade, gender or school score. In this study, students preferred a computer-supported laboratory mostly followed by a classic laboratory with a computer simulation in last place, regardless of students’ grade, gender or academic scores.     

The Molecular Biology Notebook on CD-Rom – A step toward the virtual laboratory

The Molecular Biology Notebook is a teaching tool for molecular biology, developed at the Institute of Arable Crops Research, Rothamsted, in association with local schools and the University of Luton. It is a collection of software, consisting of a course on molecular biology, a browser to read the course and also navigate the Internet, and simulation software to perform molecular biology experiments.