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201	A Curriculum Unit to Provide Enrichment Activities for Talented Students in Biology Gibson-Morrissey, Mary Angela 01 January 1978 (has links) The foregoing fable casts much doubt on some elements of the instructional process. All children cannot fit in the same shoe size just as all children cannot learn the same things at the same rate, following the same teaching strategies. These individual differences should be taken into consideration. The situation is not at all helped by attaching labels to the students. Children are not cows that we herd from one grade to another, all needing the same nutritional requirements. They should be compared more to various species of plants. Some may be like the cactus which only needs water once a month, and too much water would kill it. Other plants may need watering every day. Likewise, all students are individuals and have many different needs.The problem to be examined here concerns the “gifted feet" which were put into the "red shoes". The word "gifted", in referring to students, seems to imply that these students are all geniuses, and, therefore, the term needs some clarification. For the purpose of this paper, the term "gifted" is broadened to also include the "talented" and/or “highly motivated.” For the sake of simplicity, the term "talented" will be used throughout the rest of this paper, but with the understanding that the other two terms are included in the meaning. Thesis University of North Florida education science secondary Curriculum and Instruction Education Educational Methods Science and Mathematics Education
202	The Use of Part-Time Faculty in Associate Degree Nursing, Social Science, and Biological Science Programs Shepard, Pamela Ann 08 1900 (has links) This study surveyed the opinions of academic administrators of associate degree nursing programs, community college social science programs, and community college biological science programs regarding major benefits and concerns associated with the employment of part-time faculty. This study found that most part-time social science faculty teach in the classroom, half participate in non-teaching faculty activities, and most are paid a contract amount per course or credit hour. Part-time biological science faculty differed only in that most teach a combination of classroom and lab/practicum. Part-time nursing faculty differed in all three areas. Most part-time nursing faculty teach in lab or practicum settings, most participate in more non-teaching activities than other part-time faculty, and most are paid an hourly wage. However, the benefits and concerns associated with the employment of part-time nursing faculty were not significantly different from those identified by academic administrators of the other programs with one exception. Academic administrators felt that part-time nursing faculty expose students to the latest technologies in specialty areas and part-time social science faculty do not. The benefits cited by the respondents, that were in addition to the benefits most frequently cited in the literature, include increased interaction with the community and the ability to "try out" prospective full-time faculty. The concerns cited by respondents, that were in addition to the concerns most frequently cited in the literature, include the inability to find qualified part-time faculty to fill available positions and the concern that the employment of part-time faculty causes resentment among full-time faculty. The results from this study indicate that the literature pertaining to the benefits and concerns associated with the employment of social science and biological science part-time faculty in community colleges can be used to develop policies regarding part-time faculty in associate degree nursing programs. part-time teachers part-time college faculty community college major benefits associate degree nursing program College teachers, Part-time. Biology -- Study and teaching.
203	As representações e o que aprendemos a \"ver\" sobre o ciclo de vida das plantas / The graphical representations and what realize from them about the life cycle of the plants Santana, Margarete Alves Silva 22 November 2013 (has links) Analiso nesta dissertação as representações sobre o ciclo de vida das plantas de onze coleções de livros didáticos de ciências aprovados pelo Programa Nacional de Livros Didático (PNLD) referente ao ano de 2011 para, em um segundo momento, focar nas mensagens visivas das representações de cada uma das divisões de plantas briófitas, pteridófitas, gimnospermas e angiospermas. As mensagens visivas permitir-me-iam caracterizar as transformações ocorridas tanto na forma de representar o ciclo quanto nas linguagens utilizadas nas estruturas representacionais que, na maioria das vezes, não condizem com os títulos empregados para nomeá-las. Lançando mão dos pressupostos da tríade pierciana (ícone-objeto-símbolo) a análise semiótica empreendida forneceu-me subsídios para, em uma terceira etapa da pesquisa, coletar desenhos junto aos sujeitos da pesquisa no que tange ao ciclo de vida das plantas, cujos ícones apresentaram os indícios que caracterizam o objeto, ou seja, o ciclo de vida das plantas - encerrado em simbologias com significados que reverberam em contextos históricos específicos, como uma lei própria das estruturas iconográficas. Nos ciclos de vida das plantas essas simbologias se encerram no círculo, envolvendo a vida das plantas como algo ininterrupto, isto é, a planta germina, cresce, desenvolve-se, reproduz e volta a germinar. Baseada nas premissas piercianas constatei que embora as imagens no ensino de ciências sejam de fundamental importância, elas interferem sobremaneira na aprendizagem dos fenômenos naturais, modificando percepções entre os ícones e o objeto real, fato este evidenciado quando comparei as representações imagéticas dos sujeitos desta pesquisa com as representações dos livros didáticos de ciências nos quais não há indícios da finalização do ciclo vital das plantas: a representação da senescência e da morte das plantas. / The object of this essay is the analysis of the representations about vegetables life cycle included in eleven science didactic books approved by PNLD related to the year of 2011. The intention is to focus on the visual messages delivered by the representations of each one of the vegetables division bryophytes, pteridophytes, gymnosperms and angiosperms. Those visual messages would allow me to identify the changes occurred both in the way to represent the cycle as well the language used to perform it. Most of the time these representations do not match with the titles used to designate them. In light of the pierciana triad (icon-object-symbol) the semiotics analysis used during the third phase of this study provided me subsidies to collect drawings from the research subjects regarding the vegetable life cycle. Such icons showed evidences that the feature of the object (vegetables life cycle) is enclosed in symbols linked to specific historic contexts like a particular law applied in iconographic structures. These symbols used to show the vegetables life cycle like something uninterrupted. In other words, the vegetables would germinate, grow, develop, breed and back to germinate in an endless cycle. Even though images are fundamental in the science teaching process I was able to conclude (Based on the PIERCIANAS premises) that the images may induce relevant misunderstandings between Icons and real objects. The perception of the natural phenomenon may be strongly corrupted. The evidences of this statement became crystal clear when I compared the image representations of the subjects of this research with the images of the science didactic books that dont clearly show the end of the life cycle of the vegetables: A senescence representation of the vegetables death. Biologia - Estudo e ensino Biology - Study and teaching Ciclo de vida Ciências - Estudo e ensino Life cicle Livro didático - Análise Plantas - Estudo e ensino. Plants - Study and teaching. Science - Study and teaching Semiotcs Semiótica Textbooks - Analysis
204	As representações e o que aprendemos a \"ver\" sobre o ciclo de vida das plantas / The graphical representations and what realize from them about the life cycle of the plants Margarete Alves Silva Santana 22 November 2013 (has links) Analiso nesta dissertação as representações sobre o ciclo de vida das plantas de onze coleções de livros didáticos de ciências aprovados pelo Programa Nacional de Livros Didático (PNLD) referente ao ano de 2011 para, em um segundo momento, focar nas mensagens visivas das representações de cada uma das divisões de plantas briófitas, pteridófitas, gimnospermas e angiospermas. As mensagens visivas permitir-me-iam caracterizar as transformações ocorridas tanto na forma de representar o ciclo quanto nas linguagens utilizadas nas estruturas representacionais que, na maioria das vezes, não condizem com os títulos empregados para nomeá-las. Lançando mão dos pressupostos da tríade pierciana (ícone-objeto-símbolo) a análise semiótica empreendida forneceu-me subsídios para, em uma terceira etapa da pesquisa, coletar desenhos junto aos sujeitos da pesquisa no que tange ao ciclo de vida das plantas, cujos ícones apresentaram os indícios que caracterizam o objeto, ou seja, o ciclo de vida das plantas - encerrado em simbologias com significados que reverberam em contextos históricos específicos, como uma lei própria das estruturas iconográficas. Nos ciclos de vida das plantas essas simbologias se encerram no círculo, envolvendo a vida das plantas como algo ininterrupto, isto é, a planta germina, cresce, desenvolve-se, reproduz e volta a germinar. Baseada nas premissas piercianas constatei que embora as imagens no ensino de ciências sejam de fundamental importância, elas interferem sobremaneira na aprendizagem dos fenômenos naturais, modificando percepções entre os ícones e o objeto real, fato este evidenciado quando comparei as representações imagéticas dos sujeitos desta pesquisa com as representações dos livros didáticos de ciências nos quais não há indícios da finalização do ciclo vital das plantas: a representação da senescência e da morte das plantas. / The object of this essay is the analysis of the representations about vegetables life cycle included in eleven science didactic books approved by PNLD related to the year of 2011. The intention is to focus on the visual messages delivered by the representations of each one of the vegetables division bryophytes, pteridophytes, gymnosperms and angiosperms. Those visual messages would allow me to identify the changes occurred both in the way to represent the cycle as well the language used to perform it. Most of the time these representations do not match with the titles used to designate them. In light of the pierciana triad (icon-object-symbol) the semiotics analysis used during the third phase of this study provided me subsidies to collect drawings from the research subjects regarding the vegetable life cycle. Such icons showed evidences that the feature of the object (vegetables life cycle) is enclosed in symbols linked to specific historic contexts like a particular law applied in iconographic structures. These symbols used to show the vegetables life cycle like something uninterrupted. In other words, the vegetables would germinate, grow, develop, breed and back to germinate in an endless cycle. Even though images are fundamental in the science teaching process I was able to conclude (Based on the PIERCIANAS premises) that the images may induce relevant misunderstandings between Icons and real objects. The perception of the natural phenomenon may be strongly corrupted. The evidences of this statement became crystal clear when I compared the image representations of the subjects of this research with the images of the science didactic books that dont clearly show the end of the life cycle of the vegetables: A senescence representation of the vegetables death. Biologia - Estudo e ensino Ciclo de vida Ciências - Estudo e ensino Livro didático - Análise Plantas - Estudo e ensino. Semiótica Biology - Study and teaching Life cicle Plants - Study and teaching. Science - Study and teaching Semiotcs Textbooks - Analysis
205	How Does Student Understanding of a Concept Change Throughout a Unit of Instruction? Support Toward the Theory of Learning Progressions Dyer, Brian Jay 10 December 2013 (has links) This study documented the changes in understanding a class of eighth grade high school-level biology students experienced through a biology unit introducing genetics. Learning profiles for 55 students were created using concept maps and interviews as qualitative and quantitative instruments. The study provides additional support to the theory of learning progressions called for by experts in the field. The students' learning profiles were assessed to determine the alignment with a researcher-developed learning profile. The researcher-developed learning profile incorporated the learning progressions published in the Next Generation Science Standards, as well as current research in learning progressions for 5-10th grade students studying genetics. Students were found to obtain understanding of the content in a manner that was nonlinear, even circuitous. This opposes the prevailing interpretation of learning progressions, that knowledge is ascertained in escalating levels of complexity. Learning progressions have implications in teaching sequence, assessment, education research, and policy. Tracking student understanding of other populations of students would augment the body of research and enhance generalizability. Curriculum and Instruction Educational Methods
206	Integrating K-W-L Prompts into Science Journal Writing: Can Simple Question Scaffolding Increase Student Content Knowledge? Wagner, Brandon Joel 24 September 2014 (has links) Writing-to-learn strategies have been administered in the past to enrich student learning. The purpose of this study was to see if K-W-L prompts in science journal writing could benefit student content knowledge within biology. Two high school biology classes were provided with learning journals. The journals given to the students during the treatment unit were provided with K-W-L question prompts to guide student learning while during the comparison unit students were given an open ended writing assignment. Pre and posttests were administered to determine student-learning gains. Student motivations and opinions of the treatment were collected through student interviews. The combined results were used to determine to what extent could K-W-L prompts in science journal writing influence comprehension of content knowledge. This study found there to be no difference in student learning gains when utilizing the K-W-L literacy strategy versus another free-writing activity. When scored, student K-W-Ls total scores did correlate to student success on unit tests. This opens up the potential for K-W-Ls to serve as an adequate tool for formative assessment. Here the K-W-L could be expanded to enrich student question asking, potentially aid students learning English, and potentially be used by students without teacher scaffolding. Other Rhetoric and Composition Science and Mathematics Education
207	The difference between traditional learning environment and information enriched learning environment on the acquisition andtransfer of higher order thinking skills in a biological context Yip, Wing-shun., 葉榮信. January 1998 (has links) published_or_final_version / Education / Master / Master of Education Science - Study and teaching (Secondary) Biology - Computer-assisted instruction. Science - Computer-assisted instruction.
208	Using student difficulties to identify and model factors influencing the ability to interpret external representations of IgG-antigen binding. Schonborn, Konrad Janek. January 2005 (has links) Scientific external representations (ERs), such as diagrams, images, pictures, graphs and animations are considered to be powerful teaching and learning tools, because they assist learners in constructing mental models of phenomena, which allows for the comprehension and integration of scientific concepts. Sometimes, however, students experience difficulties with the interpretation of ERs, which· has a negative effect on their learning of science, . . including biochemistry. Unfortunately, many educators are not aware of such student difficulties and make the wrong assumption that what they, as experts, consider to be an educationally sound ER will necessarily promote sound. learning and understanding among novices. On the contrary, research has shown that learners who engage in the molecular biosciences can experience considerable problems interpreting, visualising, reasoning and learning with ERs of biochemical structures and processes, which are both abstract and often represented by confusing computer-generated symbols and man-made markings. The aim of this study was three-fold. Firstly, to identify and classify students' conceptual and reasoning difficulties with a selection of textbook ERs representing· IgG structure and function. Secondly, to use these difficulties to identify sources of the difficulties and, therefore, factors influencing students' ability to interpret the ERs. Thirdly, to develop a model of these factors and investigate the practical applications of the model, including guidelines fOf improving ER design and the teaching and learning with ERs. The study was conducted at the University of KwaZulu-Natal, South Africa and involved a total of 166 second and third-year biochemistry students. The research aims were addressed using a p,ostpositivistic approach consisting of inductive and qualitative research methods. Data was collected from students by means of written probes, audio- and video-taped clinical interviews, and student-generated diagrams. Analysis of the data revealed three general categories of student difficulties, with the interpretation of three textbook ERs depicting antibody structure and interaction with antigen, termed the process-type (P), the. structural-type (S) and DNA-related (D) difficulties. Included in the three general categories of difficulty were seventeen sub-categories that were each classified on the four-level research framework of Grayson et al. (2001) according to v how much information we had about the nature ofeach difficulty and, therefore, whether they required further research. The incidences of the classified difficulties ranged from 3 to 70%, across the student populations and across all three ERs. Based on the evidence of the difficulties, potential sources of the classified difficulties were isolated. Consideration of the nature of the sources of the exposed difficulties indicated that at least three factors play a major role in students' ability to interpret ERs in biochemistry. The three factors are: students' ability to reason with an ER and with their own conceptual knowledge (R), students' understanding (or lack thereof) of the concepts of relevance to the ER (C), and the mode in which the desired phenomenon is represented by the ER (M). A novel three-phase single interview technique (3P-SIT) was designed to explicitly investigate the nature of the above three factors. Application of3P-SIT to a range of abstract to realistic ERs of antibody structure and interaction with antigen revealed that the. instrument was extremely useful for generating data corresponding to the three factors.. In addition; analysis of the 3P-SIT data showed evidence for the influence ofone factor on another during students' ER interpretation, leading to the identification of a further four interactive factors, namely the reasoning-mode (R-M), reasoning conceptual (R-C), conceptual-mode (C-M) and conceptual-reasoning-mode (C-R-M) factors. The Justi and Gilbert (2002) modelling process was employed to develop a model of the seven identified factors. Empirical data generated using 3P-SIT allowed the formulation and validation of operational definitions for the seven factors and the expression of the model as a Venn diagram, Consideration ofthe implications of the model, yielded at least seven practical applications of the model, including its use for: establishing whether sound or unsound interpretation, learning and visualisation of an ER has occurred; identifying the nature and source of any difficulties; determining which of the factors of the model are positively or negatively influencing interpretation; establishing what approaches to ER design and teaching and learning with ERs will optimise the interpretation and learning process; and, generally framing and guiding researchers', educators' and authors' thinking about the nature of students' difficulties with the interpretation of both static and animated ERs in any scientific context. In addition, the study demonstrated how each factor of the expressed model can be used to inform the design of strategies for remediating or preventing students' difficulties with the interpretation of scientific ERs, a target for future research. / Thesis (Ph.D.)-University of KwaZulu-Natal, Pietermaritzburg, 2005. Biochemistry--Charts, diagrams, etc. Visual literacy--Study and teaching. Visualization. Molecular biology--Study and teaching. Biochemistry--Study and teaching. Cognition. Science--Study and teaching. Theses--Biochemistry.
209	Development of a taxonomy for visual literacy in the molecular life sciences. Mnguni, Lindelani Elphas. January 2007 (has links) The use of external representations (ERs) such as diagrams and animations in science education, particularly in the Molecular Life Sciences (MLS), has rapidly increased over the past decades. Research shows that ERs have a superior advantage over text alone for teaching and learning. Research has also indicated a number of concerns coupled with the use of ERs for education purposes. Such problems emanate from the mode of presentation and/or inability to use ERs. Regarding the later, a number of factors have been identified as major causes of student difficulties and they include visual literacy as one of the major factors. Given that little has been done to understand the nature of VL in the MLS the current study was conducted with the general aim of investigating this area and devising a way to measure the visual literacy levels of our students. More specifically, this study addressed the following research questions: i) What is the nature of visual literacy in MLS?; ii) Can specific levels of visual literacy be defined in the MLS?; and iii) Is a taxonomy a useful way of representing the levels of visual literacy for MLS? To respond to these questions, the current literature was used to define the nature of visual literacy and the visualization skills (VSs). These were then used to develop a Visual Literacy Test made up on probes in the context of Biochemistry. In these probes, the VSs were incorporated. The test was administered to 3rd year Biochemistry students who were also interviewed. Results were analysed qualitatively and quantitatively. The later analysis utilized the Rasch model to generate an item difficulty map. The results of the current study show that visual literacy is multifaceted in nature and is context based in that it requires specific propositional knowledge. In line with this, it was found that visual literacy is expressed through a cognitive process of visualization which requires VSs. Based on the performance of these skills, learners’ optimal visual literacy in the context of the MLS can be defined. Such performance can be assessed through the development of probes in the Biochemistry context. Furthermore, the current research has shown that using probes, the difficulty degree of each VS can be determined. In this instance, the Rasch model is a preferred method of ranking VSs in the context of Biochemistry in order of difficulty. From this, it was shown that given the uniqueness of each skill’s degree of difficulty, each skill can thus be regarded as a level of visual literacy. Such levels were defined in terms of the norm difficulty obtained in the current study. Given the multifaceted nature of visual literacy, the current study adopted the view that there are infinite number of VSs and hence the number of levels of visual literacy. From the variation in the degree of difficulty, the study showed that there are nonvisualization and visualization type difficulties which contribute to the differences in visual literacy levels between Biochemistry students. In addition to this, the current study showed that visual literacy in the MLS can be presented through a taxonomy. Such a taxonomy can be used to determine the level of each VS, its name and definition, typical difficulties found in the MLS as well as the visualization stage at which each skill is performed. Furthermore, this taxonomy can be used to design models, assess students’ visual literacy, identify and inform the remediation of students’ visualization difficulties. While the study has successfully defined the nature of visual literacy for the MLS and presented visual literacy in a taxonomy, more work is required to further understand visual literacy for the MLS, a field where visual literacy is very prevalent. / Thesis (M.Sc.) - University of KwaZulu-Natal, Pietermaritzburg, 2007. Visual literacy. Visualization. Biochemistry--Charts, diagrams, etc. Biochemistry--Study and teaching. Visual literacy--Study and teaching. Molecular biology--Study and teaching. Charts, diagrams, etc. Theses--Biochemistry.
210	Software interativo como ferramenta para a otimização do ensino de biologia celular / Interactive software as a tool for optimization of cell biology teaching Costa, Jessé Murilo 19 October 2017 (has links) Acompanha: Produção técnica / A aprendizagem de Biologia Celular no Ensino Médio apresenta alguns obstáculos aos alunos, que são intrínsecos ao conteúdo. Primeiramente, há um vocabulário relativamente extenso de termos que não fazem parte do cotidiano. Segundo ponto, esses termos podem se relacionar de maneiras complexas que são difíceis de assimilar. Finalmente, vários processos biológicos acontecem em etapas dinâmicas, que podem ser difíceis de deduzir a partir de imagens estáticas. O objetivo geral deste trabalho foi desenvolver um software educacional que pudesse auxiliar no processo de ensino e aprendizagem de Biologia Celular no Ensino Médio. Dois princípios usados na ferramenta foram a interatividade e a animação gráfica. A pesquisa teve como universo, duas turmas de primeiro ano do Ensino Médio técnico integrado em agroecologia e informática totalizando 80 alunos de uma escola pública Federal do Estado do Paraná e foi baseada no desenvolvimento, aplicação e teste de eficácia de um jogo tendo como foco o ensino de síntese proteica e seus mecanismos de funcionamento, assunto vinculado ao estudo da Biologia Celular. Os testes de eficácia foram feitos iniciando-se com a aplicação de uma questão aberta que procurou levantar informações sobre o nível de conhecimento do aluno acerca do assunto após a aplicação de uma aula expositiva e posterior aplicação da mesma questão como pós teste, depois da aplicação do jogo em sala. Os resultados foram avaliados e caraterizados a partir de quatro categorias de aprendizado em Biologia, sendo essas, Nominal, Funcional, Estrutural e Multidimencional em ordem crescente de nível de aprendizado. Como resultado, constatamos pela evolução das questões formuladas pelos alunos, frente às categorias citadas, que o produto teve influência positiva no aprendizado e pode contribuir para a dinamicidade no ensino da Biologia Celular no Ensino Médio. / The learning of Cell Biology in High School presents some obstacles to students, which are intrinsic to the content. First, there is a relatively extensive vocabulary of terms that is not part of everyday life. Second point, these terms may relate in complex ways that are difficult to assimilate. Finally, several biological processes take place in dynamic steps, which can be difficult to infer from static images. The general objective of this work is to develop an educational software that could aid in the teaching and learning process of Cell Biology in High School. Two principles used in the tool were the interactivity and graphical animation. The research had as a universe two first year classes of an Integrated Technical High School Course in Agroecology and Informatics totaling 80 students of a public federal school of the State of Paraná and it was based in the development, application and effectiveness test of a game having as focus the teaching of protein synthesis and its mechanisms of functioning, a subject linked to the study of Cell Biology. Efficacy tests were performed through an application of an open question, in order to evaluate the level of the students’ knowledge on the subject after an expositive class and a later application of the same question as an post evaluation, after the application of the game in class. The results were evaluated and characterized from four categories of learning in Biology, such as, Nominal, Functional, Structural and Multidimensional in ascending order of learning level. As a result, we verified by the evolution of the questions formulated by the students, given the aforementioned categories, that the product had a positive influence on learning and can contribute to the dynamism in the teaching of Cell Biology in High School. CNPQ::CIENCIAS HUMANAS Biologia - Estudo e ensino Células - Estudo e ensino Sistemas de computação interativos Jogos para computador Aprendizagem Biology - Study and teaching Cells - Study and teaching Interactive computer systems Computer games Learning Ensino de Ciências e Matemática

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