View metadata, citation and similar papers at core.ac.uk Special Technical Feature brought to you by CORE provided by Universidade do Minho: RepositoriUM A CONCEPT INVENTORY FOR MOLECULAR LIFE SCIENCES: HOW WILL IT HELP YOUR TEACHING PRACTICE? Susan Howitt1*, Trevor Anderson2, Manuel Costa3, Susan Hamilton4 and Tony Wright4 1Australian National University, ACT 0200 2University of KwaZulu-Natal, Pietermaritzburg, South Africa 3University of Minho, Braga, Portugal 4University of Queensland, QLD 4072 *Corresponding author: [email protected] Textbooks for biology are getting bigger and bigger with greater understanding of the nature of student difficulties, each edition, but does this mean that our students are which in turn can lead to the development of more learning more? Most of us would answer no to this effective teaching and learning strategies. Our project aims question. In fact, the learning by our students is to begin developing concept inventories for the molecular sometimes seen as disappointing, as the core concepts or life sciences and is funded by the Australian Teaching and the 'big ideas' of biology appear to be obscured by rote Learning Council and the International Union of learning of detailed content. Educators have recognised Biochemistry and Molecular Biology (IUBMB). that the information explosion in biology, particularly in It is clear from the education literature that students the molecular life sciences, has created a significant often construct their own understandings that are at odds problem in selecting what core concepts and principles with scientific concepts (3). These unscientific we should be teaching our students (1). Another conceptions, sometimes called 'misconceptions' or consequence of the focus on specific content in the 'alternative conceptions', can interfere with the learning of structure and assessment of many secondary and tertiary correct scientific ideas. Thus for teaching to be effective, it biology courses is that students obtain little idea of the is important to try to identify students' unscientific nature of science and may come to see science as a conceptions and ways of reasoning and then devise collection of unchanging facts to be learnt. In addition, the appropriate teaching strategies to remediate them (4). molecular life sciences are becoming more This is where the concept inventory plays a role. A well- interdisciplinary, more systems-focussed and increasingly designed set of questions will provide essential dependent on chemistry, physics and maths. In information on what students think and on their ability to considering these issues, it is timely to remember the use core concepts. Concept inventories differ from educational philosophy expressed by A.N. Whitehead in assessment tests in several important ways: they are 1929 (2), "Let the main ideas which are introduced into a aimed at examining conceptual understanding; they may child's education be few and important, and let them be not cover detailed content knowledge; they are based on thrown into every combination possible. The child should rigorous research into student misconceptions; and make them his own, and should understand their questions are often worded to reflect common student application here and now." misconceptions (5). Results from the use of concept Focussing on the main ideas is clearly what we should be inventories provide information on levels of student doing in the molecular life sciences, but learning at the understanding and also allow an assessment of the conceptual level is harder to achieve and to assess than the effectiveness of teaching (for example, the same test may learning of content knowledge. As it is no longer possible be used pre- and post-instruction). Most importantly, the to cover everything, we must choose - what are the most information obtained also can be used to improve important aspects of biology that a student really needs to teaching and curriculum design, for example, by be familiar with? What skills do students need to be able providing feedback to students and by informing the to cope with the changing face of biology? How are we design of remediation strategies to correct students' going to teach both the content and the skills? How will conceptual and reasoning difficulties. we assess whether the student has in fact mastered the The effectiveness of a concept inventory has been well crucial ideas? We would benefit from a validated documented in disciplines other than biology. The idea of curriculum framework and from educational research a concept inventory first arose in physics education more providing evidence on what we should teach our than fifteen years ago through the work of David students. One way to address these challenges is by using Hestenes and his graduate students at Arizona State a concept inventory, which is a standardised test that aims University (6), who wrote a test covering the conceptual to examine student understanding of previously identified basis of mechanics (the Force Concept Inventory) and core concepts or big ideas. Results from such tests allow a administered it to their introductory physics course. To Page 14 AUSTRALIAN BIOCHEMIST Vol 39 No 3 December 2008 Special Technical Feature their dismay, their students failed on questions that the life sciences will bring about a transformation of lecturers and tutors thought 'trivial'. One study showed education in our discipline, similar to what has that, at the beginning of the course, 80% of students occurred in physics. Development of concept could state Newton's third law but at the end, only 15% inventories in biology has lagged behind other could demonstrate that they actually understood what it sciences, but there are now a number of projects meant (7). This was despite the fact that many of the underway. In addition to ours, several other projects same students performed well on exams, indicating a are addressing specific areas or topics where research lack of alignment between the standard assessment tools into students' understanding has identified conceptual and the lecturers' objectives. difficulties (for reports from two meetings on The Force Concept Inventory, which has now been conceptual assessment in biology, see extensively validated and widely used, has provided a http://bioliteracy.net/ and references 5 and 13). The model for the development of concept inventories that remainder of this article will focus on our concept have been used in a variety of fields, particularly in inventory project. A first step in developing a concept physics and engineering, to provide invaluable inventory is deciding on the core concepts that a information for both students and their teachers (8). One student needs to understand. This is surprisingly advantage of a good concept inventory is that it not only difficult to articulate. There is considerable variation in identifies failures in student understanding, but can also what is covered in introductory biology courses and be used to assess the effectiveness of teaching strategies many concepts that underlie the molecular life sciences designed to remediate these difficulties. Again, this has are, of course, those of chemistry and physics. We been abundantly demonstrated in physics, with results began by attempting to generate a list of 'big ideas' in from tests performed pre- and post-instruction leading to biology that could be used as a conceptual framework the conclusion that a number of different 'interactive to direct our thinking on question coverage and design. engagement' teaching approaches result in increased A big idea should (a) be at the heart of expert student understanding (9-12). Thus a concept inventory understanding, (b) be inherently abstract, with the paves the way for educators to gain a greater meaning not always obvious to students, and (c) serve understanding of student difficulties, which should then as an organiser, connecting concepts, and be applicable lead to more effective teaching and learning strategies, in a range of topics in the subject (Fig. 1). and for researchers to obtain new and needed Our strategy in designing questions was to use the big knowledge about student learning. ideas to help us think about what is important for a So where does this leave biology? It is hoped that the student to know, rather than testing the big ideas directly. development of concept inventories for the molecular Each idea will have relevance to more than one topic or Information & Aqueous communication Compartmentalisation Catalysis environment BIG IDEAS Molecular Self Energy & Complexity evolution assembly Regulation organisation of molecular structure across substrate solubility, signalling membranes binding/ buffering inhibition complementarity, transport, ∆G, protein folding binding stability constant avoidance of shape, polarity equilibrium KEY EQUILIBRIUM CONCEPT Fig. 1. The big ideas of the molecular life sciences. Also shown is the relationship between one key concept, equilibrium and the big ideas. Vol 39 No 3 December 2008 AUSTRALIAN BIOCHEMIST Page 15 Special Technical Feature content area, so our next step was to think about concepts can be validated and compared easily and can then be and how they fitted into each big idea. This then led to widely used by the community of educators. This has content areas where this conceptual knowledge was proved crucial in physics education (12). needed, which provided a context for question design. In dealing with the concept of equilibrium, we have For example, we looked at the concept of equilibrium. It developed a series of questions in three different is clear that this has relevance to many of the big ideas, as contexts: ligand binding (Fig. 2); buffers; and enzyme shown in Fig. 1, and therefore is a concept that is kinetics. These questions are currently being tested in fundamental to the molecular life sciences. two ways. Firstly, we have given the test (as a non- There are a number of factors to consider in designing assessed activity) to 210 students at the University of concept inventory questions. The questions must be Queensland, with further testing underway at the based on rigorous research into student misconceptions.