An Analysis of an Interactive Videodisc System for Teaching Language Skills to Deaf Students

An interactive videodisc system designed to teach language concepts to deaf students was evaluated in a classroom trial. An experimental group of 18 students spent 60 twenty‐minute sessions over a five‐month period learning language concepts by interacting with the system while a control group of 16 students learned the same concepts in their regular classroom setting. Both groups made significant progress from pre‐ to post‐test on two criterion‐referenced testsdeveloped by project staff. Experimental students were enthusiastic about the videodisc, felt that their language skills had improved, and were anxious to continue working with the system.     

The impact of three‐dimensional computational modeling on student understanding of astronomical concepts: a quantitative analysis

The increased availability of computational modeling software has created opportunities for students to engage in scientific inquiry through constructing computer‐based models of scientific phenomena. However, despite the growing trend of integrating technology into science curricula, educators need to understand what aspects of these technologies promote student learning. This study used a multi‐method research approach involving both quantitative (Paper 1) and qualitative data (Paper 2) to examine student conceptual understanding of astronomical phenomena, relative to two different instructional experiences. Specifically, based on students' understandings of both spatial and declarative knowledge, we compared students who had constructed three‐dimensional computational models with students who had experienced traditional lecture‐based instruction. Quantitative analysis of pre‐interview and post‐interview data revealed that construction of three‐dimensional models best facilitated student understandings of spatially related astronomical concepts — whereas traditional instruction techniques best facilitated student understandings of fact‐oriented astronomical knowledge. This paper is the first in a two‐paper set that continues our line of research into whether problem‐based courses such as the Virtual Solar System course can be used as a viable alternative to traditional lecture‐based astronomy courses.     

The Relative Effectiveness of the Reflective and the Lecture Approach Methods on the Achievement of High School Social Studies Students

The aim of this study was to find out whether the achievement of high school social studies students differs significantly according to whether they are taught by the reflective teaching method or the lecture approach method. A stratified random sample of 215 year three social studies students was randomly assigned to two groups: 107 students into the reflective approach group and 108 into the lecture approach group. An achievement test was used as the pre‐ and the post‐test. The means of the aggregate mean performance scores were compared by the use of Student's t‐test. There was no significant difference between the two groups on the pre‐test scores but there was a significant difference between the post‐test scores, in favour of the group taught by the reflective approach method.     

Development of decision‐making skills and environmental concern through computer‐based,scaffolded learning activities

This article focuses on the development of decision‐making skills and environmental concern by 11‐ and 12‐year‐old students through computer‐based, scaffolded learning activities. The enacted activities provided necessary scientific information and allowed for the consideration of multiple aspects of the problem, the study of the effects of every possible solution and the formulation and balancing of criteria. The optimization strategy for decision making was adopted, because it allows for the development of compensatory thinking which is more relevant to actual situations of decision making. Twelve students participated in the pilot enactment of the proposed activities. Data collection relied on students’ reports and pre‐ and post‐ tests as well as a closed questionnaire designed to measure students’ environmental concern. The teaching intervention proved quite successful in enhancing the decision‐making skills of the participating children. Moreover, students’ performance on the environmental concern questionnaire correlated in interesting ways with the improvement of decision‐making skills.     

Independent learning modules enhance student performance and understanding of anatomy

Didactic lessons are only one part of the multimodal teaching strategies used in gross anatomy courses today. Increased emphasis is placed on providing more opportunities for students to develop lifelong learning and critical thinking skills during medical training. In a pilot program designed to promote more engaged and independent learning in anatomy, self‐study modules were introduced to supplement human gross anatomy instruction at Joan C. Edwards School of Medicine at Marshall University. Modules use three‐dimensional constructs to help students understand complex anatomical regions. Resources are self‐contained in portable bins and are accessible at any time. Students use modules individually or in groups in a structured self‐study format that augments material presented in lecture and laboratory. Pilot outcome data, measured by feedback surveys and examination performance statistics, suggest that the activity may be improving learning in gross anatomy. Positive feedback on both pre‐ and post‐examination surveys showed that students felt the activity helped to increase their understanding of the topic. In concordance with student perception, average examination scores on module‐related laboratory and lecture questions were higher in the two years of the pilot program compared with the year before its initiation. Modules can be fabricated on a modest budget using minimal resources, making implementation practical for smaller institutions. Upper level medical students assist in module design and upkeep, enabling continuous opportunities for vertical integration across the curriculum. This resource offers a feasible mechanism for enhancing independent and lifelong learning competencies, which could be a valuable complement to any gross anatomy curriculum. Anat Sci Educ 7: 406–416. © 2014 American Association of Anatomists.     

Exploring the Effect of Graphical Metaphors on the Performance of Learning Computer Programming Concepts in Adult Learners: a pilot study

ABSTRACT The effect of instructional materials enhanced with textual metaphors versus graphical metaphors was investigated. In the text‐plus‐textual metaphor material, the learning content described computer programming logic patterns (i.e. sequence, selection and repetition control structures) in a generic text format, followed by expository examples in the form of textual metaphors. The text‐plus‐graphical metaphor material consisted of the generic text instruction with the expository examples replaced by graphical metaphors (pictures). A total of 37 adult learners attended one lecture and two tutorials to learn how to write programming algorithms. All of the participants completed Riding and Cheema's (1991) Cognitive Styles Analysis (CSA) to measure their position on two cognitive style dimensions: Wholist‐Analytic and Verbal‐Imagery. The participants were paired based on their similar CSA ratios. One participant from each pair was given the text‐plus‐textual metaphor treatment, while the other was given the text‐plus‐graphical metaphor treatment. The treatment groups were controlled for instructional format and cognitive style. These independent variables were used to test for their effect on learning abstract computer programming concepts. Performance, as measured by the difference between pre‐test and post‐test scores, was analysed using statistical means and the QUEST probability analysis program. Both methods show that graphical metaphors improve participants’ performance. They also show that the best performance is achieved by Verbalisers, given the graphical metaphor instructional material.     

Promoting academic writing/referencing skills: Outcome of an undergraduate e-learning pilot project

Future health care professionals will require self‐directed learning skills. e‐Learning is a tool to assist in this process and therefore there is a need to develop the capacity and readiness to utilise e‐learning within educational programmes. The aim of this study was to determine if extra‐curricular online referencing and anti‐plagiarism lectures would be utilised and would ultimately improve 1st‐year undergraduate health sciences students’ performance in written assessments. A series of six online archived multimedia lectures (asynchronous) were offered. Adult learning theory principles guided the resource design. Pre‐ and post‐testing of knowledge, attitudes and computer skills was carried out. In‐person tutorials and online email support were also offered. Less than 36% (self‐report) of students accessed the online resources. The poor uptake revealed in this study is consistent with a number of other studies. These findings indicate the need for more careful scrutiny of the learning theory applied in e‐learning design. Prochaska's transtheoretical model is suggested as a framework with strong potential for e‐learning initiatives.     

How Levels of Interactivity in Tutorials Affect Students' Learning of Modeling Transportation Problems in a Spreadsheet

Do students learn to model OR/MS problems better by using computer‐based interactive tutorials and, if so, does increased interactivity in the tutorials lead to better learning? In order to determine the effect of different levels of interactivity on student learning, we used screen capture technology to design interactive support materials for modeling and solving the transportation problem in a spreadsheet. A controlled experiment was carried out and the results indicate a general support for the effectiveness of interactive tutorials in enhancing students’ learning of modeling concepts. However, the study also found that excessive interactivity increased the cognitive load for the students and hindered their learning by making it difficult for them to consolidate concepts, integrate previous knowledge, and create meaningful mental models of the process.     

Linking Biochemistry Concepts to Food Safety Using Yogurt as a Model

This laboratory activity was designed to strengthen our Food and Nutritional Science students’ knowledge of biochemistry concepts and the relationship between these concepts and food science. The result was a laboratory experience in which biochemistry concepts are taught using yogurt as a model, in order to link those concepts to food safety, an important area of food science. The students employed a colorimetric method to measure the lactase activity of bacterial strains found in commercial yogurts and were encouraged to relate the activity to bacterial lactic acid production, fermentation, and food safety. Students were assessed with pre‐ and post‐test exams, laboratory reports, class performance rubrics, and the Intrinsic Motivation Inventory (IMI). The result demonstrated that the students successfully completed the learning objectives and were motivated during the activity. This exercise could be used as a template for a simplified and engaging way to introduce food science majors, as well as other students, to complex biochemistry and molecular biology concepts using food, particularly yogurt, as a model.     

Use of interactive sessions and e‐learning in teaching anatomy to first‐year optometry students

Students enrolled in the Optometry program at the University of Manchester are required to take a functional anatomy course during the first year of their studies. Low mean scores in the written examination of this unit for the past two academic years energized staff to rethink the teaching format. Interactive sessions lasting 20 minutes each were introduced during the two hour lecture sessions. In these sessions students reinforced their anatomical knowledge learned in lectures, through playing games such as anatomy bingo and solving anatomical anagrams. In addition, five e‐learning modules were also introduced for students to complete in their own time. A pre‐ and postcourse questionnaire were distributed to obtain student views on their expectations of the course and interactive sessions. Comparisons were made between written examination results from 2008 to 2009 to written examination results from the previous five academic years to see if the interactive sessions and e‐learning modules had any impact on student knowledge. In addition, comparisons were made between student performances on the functional anatomy course with their performance in all of the other assessments taken by the students during their first year of study. Analysis of the questionnaires showed that student's expectations of the course were fulfilled and the interactive sessions were well received by the majority. There was a significant increase (P ≤ 0.01) in the mean examination score in 2008–2009 after introduction of the interactive sessions and e‐learning modules compared with scores in previous years. The introduction of interactive sessions has increased student enjoyment of the module and along with the e‐learning modules have had a positive impact on student examination results. Anat Sci Educ 3:39–45, 2010. © 2009 American Association of Anatomists.     

Cooperative learning in the tutorials of a large lecture physics class

The introduction of in-class cooperative learning to a two semester large lecture college physics sequence was evaluated using both qualitative and quantitative measuremets. The first semester of the sequence was taught using traditional formats for lectures, tutorials and laboratories. A group of six students with apparent weaknesses in their academic backgrounds (from a class size of 200) was examined closely through weekly group meetings, journal writing and formal interviews. After several weeks, the group meetings became cooperative learning sessions, and the meetings appear to have helped the students to achieve at a higher level than expected. In addition, a classroom environment survey was administered during the first semester. During the second semester, in-class cooperative learning was implemented in tutorials. Student reaction to the new tutorial format, as measured by the survey, was positive. Field notes taken during the tutorials in the second semester revealed additional positive aspects of this reform. Many of the data support the hypothesis that in-class cooperative learning addressed student concerns about the learning environment and was perceived as an effective reform by most students.     

Improving representational competence using molecular simulations embedded in inquiry activities

The present article discusses the design and impact of computer‐based visualization tools for supporting student learning and representational competence in science. Specifically, learning outcomes and student representation use are compared between eight secondary classrooms utilizing The Connected Chemistry Curriculum and eight secondary chemistry using lecture‐based methods. Results from the quasi‐experimental intervention indicate that the curriculum and accompanying visualization tool yield only small to modest gains in student achievement on summative assessments. Analysis of student representation use on pre‐ and post‐assessments, however, indicate the students in Connected Chemistry classrooms are significantly more likely to use submicroscopic representations of chemical systems that are consistent with teacher and expert representation use. The affordances of visualization tools in inquiry activities to improve students' representational competence and conceptual understanding of content in the science classroom are discussed. © 2011 Wiley Periodicals, Inc. J Res Sci Teach 48: 1137–1158, 2011     

Pathway Towards Fluency: Using ‘disaggregate instruction’ to promote science literacy

This study examines the impact of Disaggregate Instruction on students’ science learning. Disaggregate Instruction is the idea that science teaching and learning can be separated into conceptual and discursive components. Using randomly assigned experimental and control groups, 49 fifth‐grade students received web‐based science lessons on photosynthesis using our experimental approach. We supplemented quantitative statistical comparisons of students’ performance on pre‐ and post‐test questions (multiple choice and short answer) with a qualitative analysis of students’ post‐test interviews. The results revealed that students in the experimental group outscored their control group counterparts across all measures. In addition, students taught using the experimental method demonstrated an improved ability to write using scientific language as well as an improved ability to provide oral explanations using scientific language. This study has important implications for how science educators can prepare teachers to teach diverse student populations.     

Medical student retention of embryonic development: Impact of the dimensions added by multimedia tutorials

The purpose of this project was to develop Web‐based learning modules that combine (1) animated 3D graphics; (2) 3D models that a student can manipulate independently; (3) passage of time in embryonic development; and (4) animated 2D graphics, including 2D cross‐sections that represent different “slices” of the embryo, and animate in parallel. These elements were presented in two tutorials, one depicting embryonic folding and the other showing development of the nervous system after neural tube formation. The goal was to enhance the traditional teaching format—lecture combined with printed diagrams, text, and existing computer animations—with customized, guided, Web‐based learning modules that surpassed existing resources. To assess module effectiveness, we compared quiz performance of control groups who attended lecture and did not use a supporting module, with study groups who used a module in addition to attending lecture. We also assessed our students' long‐term retention of the material, comparing classes who had used the module with students from a previous year that had not seen the module. Our data analysis suggests that students who used a module performed better than those given only traditional resources if they used the module after they were already somewhat familiar with the material. The findings suggest that our modules—and possibly computer‐assisted‐instruction modules in general—are more useful if used toward the later stages of learning, rather than as an initial resource. Furthermore, our data suggest that the animation aids in long‐term retention. Both medical students at the University of Cincinnati and medical faculty from across the country commented favorably on their experiences with the embryonic development modules. Anat Sci Ed 1:252–257, 2008. © 2008 American Association of Anatomists.     

A Technology‐Enhanced Unit of Modeling Static Electricity: Integrating scientific explanations and everyday observations

What trajectories do students follow as they connect their observations of electrostatic phenomena to atomic‐level visualizations? We designed an electrostatics unit, using the knowledge integration framework to help students link observations and scientific ideas. We analyze how learners integrate ideas about charges, charged particles, energy, and observable events. We compare learning enactments in a typical school and a magnet school in the USA. We use pre‐tests, post‐tests, embedded notes, and delayed post‐tests to capture the trajectories of students’ knowledge integration. We analyze how visualizations help students grapple with abstract electrostatics concepts such as induction. We find that overall students gain more sophisticated ideas. They can interpret dynamic, interactive visualizations, and connect charge‐ and particle‐based explanations to interpret observable events. Students continue to have difficulty in applying the energy‐based explanation.     

Assessing the impact of learning environments on students' approaches to learning: comparing conventional and action learning designs

This study investigated whether students' approaches to learning were influenced by the design of university courses. Pre‐ and post‐evaluations of the approaches to learning of the same group of students concurrently enrolled in a conventional course (lectures and tutorials) and an action learning‐based course (project work, learning groups) were conducted. Students who reported themselves as more ‘typically deep’ in their approach to learning were consistent in their approaches across the different environments. However, students who reported themselves as more ‘typically surface’ were influenced to adopt deeper processing strategies in the action learning design. Students explained this ‘deep shift’ in terms of the greater expectations of learner activity and responsibility in the action learning design.     

‘I just find it boring’: Findings from an affective adolescent reading intervention

Research suggests that reading engagement and motivation are strong predictors of reading performance. Reading motivation may decline as students approach adolescence, resulting in less time spent with text. To date, there has been no research on how practitioners might directly support students to address affective factors in reading. In this exploratory case study, three disengaged, Year 8 readers received five sessions of an affective intervention aimed at helping them explore and challenge their own ambivalence towards reading. Quantitative and qualitative data from pre‐, post‐ and three‐month follow‐up indicated a range of benefits in relation to reading engagement and motivation, including improved self‐efficacy, increased participation and the usefulness of talking about affective factors in reading. Findings are further examined and implications for practitioners are discussed.     

Teaching Plan‐Do‐Study‐Act (PDSA) in a Supply Chain Context: A Paper Football In‐Class Activity

We develop a single‐class period learning game for the Plan‐Do‐Study‐Act (PDSA) improvement cycle. The experiential activity walks teams through the PDSA problem‐solving process as they create paper American footballs and improve their performance using each step of the cycle. The game is one of the first to focus on PDSA. Key benefits include increased student attention, engagement, and learning. Empirical tests show that participant pre‐ and post‐test scores regarding their understanding of each phase of PDSA improved 21.2% after completing the game. Additionally, the treatment group performed 16.6% higher than the control group. In participant perception questions, 85% of participants felt the game was more effective than lecture or reading, 93% felt the game was fun, 95% felt the game improved their understanding of PDSA, and 98% felt the game was engaging.     

A framework for scaffolding students' assessment of the credibility of evidence

Assessing the credibility of evidence in complex, socio‐scientific problems is of paramount importance. However, there is little discussion in the science education literature on this topic and on how students can be supported in developing such skills. In this article, we describe an instructional design framework, which we call the Credibility Assessment Framework, to scaffold high school students' collaborative construction of evidence‐based decisions and their assessment of the credibility of evidence. The framework was employed for the design of a web‐based reflective inquiry environment on a socio‐scientific issue, and was enacted with 11th grade students. The article describes the components of the Credibility Assessment Framework and provides the details and results of an empirical study illustrating this framework in practice. The results are presented in the form of a case study of how 11th grade students investigated and evaluated scientific data relating to the cultivation of genetically modified plants. Multiple kinds of data were collected, including pre‐ and post‐tests of students' conceptual understanding and their skills in assessing the credibility of evidence, and videotapes of students' collaborative inquiry sessions. The analysis of the pre‐ and post‐tests on students' conceptual understanding of Biotechnology and their skills in assessing the credibility of evidence revealed statistically significant learning gains. Students' work in task‐related artifacts and the analysis of two groups' videotaped discussions showed that students became sensitive to credibility criteria, questioned the sources of data and correctly identified sources of low, moderate, and high credibility. Implications for designers and educators regarding the application of this framework are discussed. © 2011 Wiley Periodicals, Inc. J Res Sci Teach 48: 711–744, 2011     

The effects of concept and vee mappings under three learning modes on Jamaican eighth graders’ knowledge of nutrition and plant reproduction

The first objective of this study was to investigate if the experimental students’ post‐test knowledge of nutrition and plant reproduction would be improved more significantly than that of their control group counterparts based on their treatment, attitudes to science, self‐esteem, gender and socio‐economic background. Treatment involved teaching the experimental students under three learning modes—pure cooperative, cooperative–competitive and individualistic whole class interpersonal competitive condition—using concept and vee mappings and the lecture method. The control groups received the same treatment but were not exposed to concept and vee mappings. This study’s second objective was to determine which of the three learning modes would produce the highest post‐test mean gain in the subjects’ knowledge of the two biology concepts. The study’s sample comprised 932 eighth graders (12–13‐year‐olds) in 14 co‐educational comprehensive high schools randomly selected from two Jamaican parishes. An integrated science performance test, an attitudes to science questionnaire and a self‐esteem questionnaire were used to collect data. The results indicated that the experimental students (a) under the three learning modes, (b) with high, moderate, and low attitudes to science, and (c) with high, moderate, and low self‐esteem, performed significantly better than their control group counterparts. The individualist whole class learning mode engendered the highest mean gain on the experimental students’ knowledge, while the cooperative–competitive learning mode generated the highest mean gain for the control group students.