The Importance of Understanding the Nature of Science for Accepting Evolution

Many students reject evolutionary theory, whether or not they adequately understand basic evolutionary concepts. We explore the hypothesis that accepting evolution is related to understanding the nature of science. In particular, students may be more likely to accept evolution if they understand that a scientific theory is provisional but reliable, that scientists employ diverse methods for testing scientific claims, and that relating data to theory can require inference and interpretation. In a study with university undergraduates, we find that accepting evolution is significantly correlated with understanding the nature of science, even when controlling for the effects of general interest in science and past science education. These results highlight the importance of understanding the nature of science for accepting evolution. We conclude with a discussion of key characteristics of science that challenge a simple portrayal of the scientific method and that we believe should be emphasized in classrooms.     

Botanical literacy: What and how should students learn about plants?

Botanists benefit from a scientifically literate society and an interested and botanically literate student population, and we have opportunities to promote literacy in our classes. Unfortunately, scientific illiteracy exists, in part, because students are technologically advanced but lack intellectual curiosity and rigor. Botanical illiteracy results from several interacting factors, including a lack of interest in plants and infrequent exposure to plant science before students reach college. If scientific or botanical literacy is a goal, we must understand what literacy means and how we can help students reach that goal. A model of biological literacy recognizes four levels; students enter courses at the lowest level possessing misconceptions about concepts; however, misconceptions can be used to our advantage, especially by using concept inventories. Inquiry-based instruction is advocated for all science courses, and learning theory supports inquiry. Seven principles of learning inform recommendations about how botanists should teach, including using themes and "thinking botanically" to illustrate all biological concepts. Overall, consideration of the botanical content taught is less critical than the methods used to teach that content. If botanists emphasize thinking and process skills with an understanding of concepts, we will prepare scientifically literate students and citizens and benefit from our efforts.     

Students' cellular and molecular explanations of genetic phenomena

Genetic concepts are assigned to three principal levels of organisation: macroscopic level, microscopic level, and submicroscopic level. In order to probe Israeli students' understanding at each level, and to gain a sense of their ability to connect ideas and concepts across different levels, we asked three different types of question. Two of the question types ask students to make a bridge between levels by asking them to explain a phenomenon at one level using concepts and processes from a different level. For example, to explain the appearance of phenotypic traits (macroscopic level) using concepts like genes or chromosomes (microscopic level). One question dealt with the molecular level only. We investigated three populations: 9^th graders, 12^th graders, and pre-service teachers. Based on our findings we suggest improvements both in terms of teaching methods and curriculum content.     

Interaction of oddball probability and primary task type on P300 in the dual-task paradigm

Using a dual-task paradigm with an oddball secondary task, P300 amplitude and latency were studied as a function of factorially manipulated oddball probability (low = .22, high = .44) and primary task type. In addition to a Baselinecondition (oddball task only), three primary tasks were used: (1) Pure Sensory;watching a movie; (2) Pure Motor (manipulating a flashlight); and (3) Sensory/Motor(using the flashlight to trace the outlines of characters in a movie). The findings included the usual significant effects of probability on amplitude. There was also a significant effect of task type on amplitude, and a significant interaction of oddball probability with task type. In the low but not high probability condition, a pure Sensory task depressed P300 amplitude. In both probability conditions, the Sensory/motortask depressed P300 amplitude. Only task type had a significant effect on P300 latency. The results confirm the ability of other labs (using Sensory/motor primary tasks) to demonstrate P300 depression at high oddball probability, in view of the difficulty in our lab of achieving P300 depression with pure sensory tasks and high oddball probabilities. The results are discussed in terms of partial overlap of processing resource pools. A preliminary report of these data was presented at the 1990 meetings of the Society for Psychophysiological Research.     

Interactive Evolution Modules Promote Conceptual Change

We developed a suite of online modules () to improve student understanding of challenging concepts in our introductory biology course at the University of Wisconsin-Madison. Here we assess the effectiveness of two of the modules, Species and Speciation and Natural Selection. In Year 1, unannounced pre-tests and post-tests were used to assess students’ prior knowledge and any gains resulting from lecture attendance alone. Then to test the effectiveness of the modules we divided the class into three groups. Group 1 was assigned the interactive speciation module and their analysis of the final case study in the module was graded. Groups 2 and 3 were controls. In Group 1, the subgroup of students whose mean scores on the first two exams in the course were <80% scored an average of 10.5 percentage points better on exam 3, a significant improvement. In contrast, none of the other student groups showed significant improvements in their grades. In Year 2, we tested the effectiveness of the online modules when offered as optional, ungraded, activities. We again saw significant improvement (+3.8 percentage points) only in those students who completed the modules and whose averages on the previous two exams were <80%. The differences in improvement between years 1 and 2 suggest that it is not enough simply to provide students with tools that help them learn; they also need an incentive in the form of a grade or course credit to use the tools most effectively.     

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.     

Correlation between Inter-Blink Interval and Episodic Encoding during Movie Watching

Human eye blinking is cognitively suppressed to minimize loss of visual information for important real-world events. Despite the relationship between eye blinking and cognitive state, the effect of eye blinks on cognition in real-world environments has received limited research attention. In this study, we focused on the temporal pattern of inter-eye blink interval (IEBI) during movie watching and investigated its relationship with episodic memory. As a control condition, 24 healthy subjects watched a nature documentary that lacked a specific story line while electroencephalography was performed. Immediately after viewing the movie, the subjects were asked to report its most memorable scene. Four weeks later, subjects were asked to score 32 randomly selected scenes from the movie, based on how much they were able to remember and describe. The results showed that the average IEBI was significantly longer during the movie than in the control condition. In addition, the significant increase in IEBI when watching a movie coincided with the most memorable scenes of the movie. The results suggested that the interesting episodic narrative of the movie attracted the subjects’ visual attention relative to the documentary clip that did not have a story line. In the episodic memory test executed four weeks later, memory performance was significantly positively correlated with IEBI (p<0.001). In summary, IEBI may be a reliable bio-marker of the degree of concentration on naturalistic content that requires visual attention, such as a movie.     

Visual pattern discrimination by population retinal ganglion cells’ activities during natural movie stimulation

In the visual system, neurons often fire in synchrony, and it is believed that synchronous activities of group neurons are more efficient than single cell response in transmitting neural signals to down-stream neurons. However, whether dynamic natural stimuli are encoded by dynamic spatiotemporal firing patterns of synchronous group neurons still needs to be investigated. In this paper we recorded the activities of population ganglion cells in bullfrog retina in response to time-varying natural images (natural scene movie) using multi-electrode arrays. In response to some different brief section pairs of the movie, synchronous groups of retinal ganglion cells (RGCs) fired with similar but different spike events. We attempted to discriminate the movie sections based on temporal firing patterns of single cells and spatiotemporal firing patterns of the synchronous groups of RGCs characterized by a measurement of subsequence distribution discrepancy. The discrimination performance was assessed by a classification method based on Support Vector Machines. Our results show that different movie sections of the natural movie elicited reliable dynamic spatiotemporal activity patterns of the synchronous RGCs, which are more efficient in discriminating different movie sections than the temporal patterns of the single cells’ spike events. These results suggest that, during natural vision, the down-stream neurons may decode the visual information from the dynamic spatiotemporal patterns of the synchronous group of RGCs’ activities.     

Problem Concepts in Evolution Part I: Purpose and Design

In 1999, Scott suggested that evolution has existential repercussions for some students because they confuse methodological naturalism with philosophical naturalism: conflating the incapacity of scientific explanations to appeal to the supernatural with the idea that God must not exist. Unfortunately, part of the reason for the confusion involves terms that are used in a technical sense by evolutionary biologists but that also convey existential meanings to the general public. Such terms therefore should be used carefully by teachers, and their scientific meanings distinguished from their common meanings. We revisit these problem concepts, particularly in light of recent papers in cognitive psychology as they relate to understanding evolution, in a two-part series of articles. Here, in part I, we address design and purpose.     

The effect of case teaching on meaningful and retentive learning when studying genetic engineering

The purpose of this study is to investigate the effects of case teaching on how students learn about genetic engineering, in terms of meaningful learning and retention of learning. The study was designed as quasi-experimental research including 63 8th graders (28 boys and 35 girls). To collect data, genetic engineering achievement tests were developed by the researchers and concept maps (CMs) were used. In the study, the experimental group (n = 31) experienced case teaching, while the comparison group (n = 32) experienced ordinary teaching. To analyse the data from achievement test scores, the Wilcoxon signed-rank test and the Mann–Whitney U test were used. In analysis of the CMs, the number of concepts, number of connecting phrases, number of examples used in the maps and shape of the maps were determined. The analyses showed that the mean achievement scores of the groups significantly differed in favour of the experimental group. Also, retention of the learning in the experimental group was observed. The number of concepts used in CMs did not significantly differ, while the number of connecting phrases in both groups differed significantly in favour of the experimental group. In addition, the students in the experimental group changed their initial hierarchical maps into branched maps, indicating more connection to other concepts.     

Values Determine the (In)Effectiveness of Informational Interventions in Promoting Pro-Environmental Behavior

Informational interventions (e.g., awareness campaigns, carbon footprint calculators) are built on the assumption that informing the public about the environmental consequences of their actions should result in increased pro-environmental intentions and behavior. However, empirical support for this reasoning is mixed. In this paper, we argue that informational interventions may succeed in improving people’s knowledge about the negative environmental consequences of one’s actions, but this knowledge will not gain motivational force if people do not consider protecting the environment an important personal value. In an experiment, we measured individual differences in value priorities, and either presented participants a movie clip that portrayed the negative environmental consequences of using bottled water, or a control movie. As predicted, we found that the environmental movie improved recipients’ knowledge of the negative environmental impact of bottled water, but this knowledge only resulted in concomitant changes in intentions and acceptability of related policies among participants who strongly endorsed biospheric (i.e. environmental) values, while having no effect on those who care less about the environment. Interestingly, the results suggest that although informational interventions are perhaps not always successful in directly affecting less environmentally-conscious recipients, they could still have beneficial effects, because they make those who strongly care about the environment more inclined to act on their values.     

Iterative design of a simulation-based module for teaching evolution by natural selection

Background

This research builds on a previous study that looked at the effectiveness of a simulation-based module for teaching students about the process of evolution by natural selection. While the previous study showed that the module was successful in teaching how natural selection works, the research uncovered some weaknesses in the design. In this paper, we used design-based research to investigate how design changes to the module affected not only students' understanding of the concepts but also their usage of misconceptions in the assessments. We present results from two studies. In study 1, we looked at gains in understanding on a pre and post-assessment for students who used the revised version of the module. We also examined misconception uses in their answer selections. In study 2, we compared the performance on a summative assessment between students who used the revised version and students who used the original version of the module. We also looked at misconception uses in their answer selections.

Results

In study 1, we saw a significant improvement in the pre-post assessment for students who used the revised version. In study 2, we did not find a significant difference on the overall performance outcome between students who used the revised and those that used the original version of the module. In both studies, however, we saw a  lower use of misconceptions after students used the revised module. In particular, we saw less use of the adaptive mutation misconception, the belief that mutations are adaptive responses to the environment and are biased towards advantageous mutations. This is promising because in the previous study there was no evidence of decreased use of this misconception.

Conclusions

Students showed learning gains on all targeted key concepts, and reduced expression of all targeted misconceptions, which was not found previously for students using the older workbook version of the module. In particular, the revised version appears to help students overcome the adaptive mutation misconception. This article demonstrates how design-based research can contribute to the ongoing improvement of evidence-based instruction in undergraduate biology classrooms.

     

What do Israeli high school students understand about biodiversity? An evaluation of the high school biology programme, ‘Nature in a World of Change’

One of the most serious problems facing our planet is the biodiversity crisis. As a solution to this problem, both scientists and educators have emphasised the need for educating people about how to conserve the Earth’s biodiversity. As a small contribution to this effort, we have designed a learning unit about biodiversity, Nature in a world of change, which has recently been implemented with 74 12th-grade Israeli high-school biology students. This unit consists of two components: an introductory module and a collection of three articles adapted from the primary scientific literature. This paper focuses on an in-depth examination with 25 students participating in the programme’s implementation. The evaluation process includes a self-assessment of prior basic ecological knowledge and a post-test focusing on concepts and issues central to the understanding of biodiversity, such as niche and Simpson’s Index. Analysis of perturbations in a food web (by an invasive species) was a special focus of the assessments, reflecting similar concerns prevalent among the scientific community. The results of this evaluation revealed that students with a solid ecological background could successfully deal with the newly acquired concepts presented in the module and the articles.     

The use of small groups in a large lecture microbiology course

In the fall of 1997, we started using small groups in our large (100–200 students) junior level introductory microbiology course. Students form five-person groups early in the semester, and work on projects within these groups throughout the semester. These projects involve exploration of concepts such as metabolism, protein synthesis, and viral reproduction strategies and the submission of a poster describing a disease of their choice at the end of the semester. We have refined the use of the small groups during the last three semesters, and student acceptance and performance have improved steadily. In the fall semester of 1998, a comprehensive assessment of the effectiveness of these group projects was performed. Students were chosen at random to participate in student consultation groups to discuss group projects. Furthermore, we utilized a master teacher-in-residence from the Rocky Mountain Teachers Education Collaborative (RMTEC). This teacher-in-residence attended our classes, spoke with students, helped with student consultation groups, and provided observations of student responses to group work activities. RMTEC also provided funds to hire a research assistant to conduct student consultation groups, analyze student evaluations of our course, and compare evaluations from before and after the implementation of group examinations. Additionally, the Center for Teaching and Learning at Colorado State University assisted with mid-semester evaluations in each subsequent semester. The results of our analysis show that small groups in large lectures can be an effective learning tool provided students are given well-designed activities with clearly defined, obtainable goals and clearly articulated guidelines. Our experience also shows that the manner in which the instructor presents the process to students affects students' willingness to participate in the process. It must be clearly articulated to students why he has incorporated active learning strategies into the course, what he hopes students will gain from the experience, and how he expects students to participate in these activities. We recognize the increase in workload on ourselves as instructors, but the benefits seem worth the additional time and effort. This paper describes the group process that we use and provides an evaluation of the effort. Journal of Industrial Microbiology & Biotechnology (2000) 25, 121–126. Received 24 March 1999/ Accepted in revised form 23 November 1999     

Treatment of specific macrovascular beds in patients with diabetes mellitus

Background

A ubiquitous dilemma in medical education continues to be whether and how to integrate research competencies into the predoctoral curriculum. Understanding research concepts is imbedded in the six core competencies for physicians, but predoctoral medical education typically does not explicitly include research education. In an effort to quickly report academic research findings to the field, this is the second in a series of articles reporting the outcomes of a research education initiative at one college of osteopathic medicine. The first article described the competency model and reported baseline performance in applied understanding of targeted research concepts. This second article reports on the learning outcomes from the inaugural year of a course in basic biomedical research concepts.

Methods

This course consisted of 24 total hours of classroom lectures augmented with web-based materials using Blackboard Vista, faculty moderated student presentations of research articles, and quizzes. To measure changes in applied understanding of targeted research concepts in the inaugural year of the course, we administered a pretest and a posttest to second year students who took the course and to first year students who took an informatics course in the same academic year.

Results

We analyzed 154 matched pretests and posttests representing 56% of the 273 first and second year students. On average, the first year (53) and second year students (101) did not differ in their mean pretest scores. At posttest the second year students showed significant improvement in their applied understanding of the concepts, whereas the first year students' mean posttest score was lower than their mean pretest score.

Conclusions

This biomedical research course appears to have increased the second year students' applied understanding of the targeted biomedical research concepts. This assessment of learning outcomes has facilitated the quality improvement process for the course, and improved our understanding of how to measure the benefits of research education for medical students. Some of the course content and methods, and the outcome measures may need to be approached differently in the future to more effectively lay the foundation for osteopathic medical students to utilize these concepts in the clinical setting.     

Helping Students Distinguish between Mixtures and Chemical Compounds

For most middle school-level students, summarizing main ideas can prove to be difficult, especially for those with low vocabulary and language acquisition skills. Working specifically with students who are English Language Learners (ELLs) and in a special education program, we discovered that teaching summarization as a reading strategy increased students' abilities to (a) acquire and use information and (b) better comprehend science concepts. In combination with other vocabulary attainment activities, summary frames enhanced the students' ability to apply information to discussions, laboratory reports, and projects. In this article, we demonstrate how to use the summary frame strategy in the context of a lesson on cells. This lesson allows for (a) knowledge of terminology through vocabulary card activities, (b) comprehension of concepts presented through summary frame activities, and (c) application of concepts through cell models and organelle classroom responsibilities.     

Problem Concepts in Evolution Part II: Cause and Chance

In a previous article, we suggested that differences in how the general public and scientists use terms such as purpose and design can lead to confusion, particularly around understanding evolution and mechanisms of evolutionary change. Here, we present two additional problem concepts, cause and chance, and discuss how these concepts lead to confusion, suggesting how to address these specific challenges to understanding evolution in light of recent research in cognitive psychology and biological concept inventories.     

Using concept maps to characterise cellular respiration knowledge in undergraduate students

ABSTRACT

Meaningful learning occurs by relating new information to and revising prior knowledge, making it essential to understand student knowledge before helping them move toward a more scientific understanding. In this study, we characterise prior knowledge about cellular respiration in undergraduate students enrolled in introductory biology by analysing student-constructed concept maps (N = 182) and interviews (N = 9). Students were instructed to create concept maps from a bank of 20 concepts with the purpose of interconnecting the processes of cellular respiration, showing how pools of ATP are generated and used, and identifying where the events of cellular respiration occur. Student maps were analysed for content, quality and organisation of knowledge. Interviews were used to corroborate inferences made from concept maps. Students had a simplified understanding of cellular respiration and its processes as evident by cognitive structures with limited quantities of schemas that were vaguely connected and linearly organised. Furthermore, students had a better understanding of glycolysis than fermentation. Instructors can use these findings to help students build better knowledge of cellular respiration by focusing on incorporating relevant schemas, creating quality connections among schemas, and organising their knowledge of cellular respiration to reflect biological complexity.     

Exploring continuity equation via a modeling activity: in the context of crowd science

Abstract

Using problems from real life contexts which is related to learners’ environment or their culture plays an important role in their learning that concept. In this regard, science educators especially physics educators search for real-life domain of theoretical concepts for effective science teaching and they consider analogical and physical models as an opportunity in their instruction. In the presented activity, we worked with 66 senior pre-service science teachers from our science teaching methods course. We used crowd movements as a real-life domain of our analogical models to scientifically explain a stampede case, then utilized physical model to explore continuity equation. Real life problem based scenarios could be used while taking advantage of the 3?D modeling in teaching of scientific principle. As a result, we found that pre-service teachers were able to make scientific explanation for causes of stampedes by using modeling activity. High school teachers and upper-level instructors could benefit from including the modeling activity introduced in this study to help their students understand the concepts related to continuity equation by designing a physical model based on an analogical model. Via the physical model, students are able to make predictions, observations, interpretations and explanations of a complex and abstract scientific phenomenon.     

Selection and Evolution with a Deck of Cards

Imparting a basic understanding of evolutionary principles to students in an active, engaging fashion can be troublesome because the logistics involved in designing experiments where students pose their own questions and use the data to test alternative hypotheses often outstrip time and financial constraints. In recent years, educators have begun publishing exercises that teach evolution using innovative, in-class experiments. This article adds to this growing forum by describing a classroom exercise that introduces the concept of evolution by natural selection in a hypothesis-driven, experimental fashion, using a deck of cards. Our standard exercise is suitable for upper-level high school and introductory biology students at the college level. In this paper, we discuss the exercise in detail and give several examples that illustrate how our games provide accessible bridges to the primary literature. Finally, we discuss how extensions of our basic exercise can be used to effectively teach advanced evolutionary concepts.