Simply InGEN(E)ious! How Creative DNA Modeling Can Enrich Classic Hands-On Experimentation

Mierdel, Julia; Bogner, Franz X.

doi:10.1128/jmbe.v21i2.1923

Cited by 7 publications

(5 citation statements)

References 10 publications

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“…As advocated by many JMBE scholars ( Table 1 , Language and communication), broader conversations about how we communicate science may increase DEI. Some papers talk about the history of oppression in science neutrally ( 79 ), which buries the struggles that certain groups, such as women, have faced in our field (a subjugating practice). On the other hand, Malotky et al ( 29 ) increased students’ awareness of oppression, privilege, and cultural differences through explicit instruction about systemic racism during collaborative course-based undergraduate research experiences (CUREs) involving community stakeholders (a liberating practice).…”

Section: Emergent Conceptual Categories From the Literaturementioning

confidence: 99%

Antiracist Opportunities in the Journal of Microbiology and Biology Education : Considerations for Diversity, Equity, and Inclusion

Nardi

2021

J Microbiol Biol Educ.

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Authors in the Journal of Microbiology and Biology Education (JMBE) have demonstrated a clear commitment to diversity, equity, and inclusion (DEI) through commentaries, instructional approaches, and research. However, analysis of JMBE literature using Kendi’s antiracist framework ( How To Be an Antiracist , 2019) offers additional opportunities for growth.

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Section: Emergent Conceptual Categories From the Literaturementioning

confidence: 99%

Antiracist Opportunities in the Journal of Microbiology and Biology Education : Considerations for Diversity, Equity, and Inclusion

Nardi

2021

J Microbiol Biol Educ.

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“…It is encouraging that even a one-day module has the power to improve students' understanding towards a more scientific point of view. Therefore, we conclude that the context of DNA structure provides a fruitful example for combining hands-on experimentation with model-based learning in an out-of-school laboratory by offering access to an exciting path of discovery of molecular phenomena using student-centered hands-on tasks [22].…”

Section: Discussionmentioning

confidence: 90%

“…One of our aims was to innovate traditional outreach programs in learning genetics by arousing students' creativity and transferring enthusiasm from arts to science classes. We developed a STEAM teaching approach (STEAM = science, technology, engineering, arts and mathematics) for an out-of-school lab setting, combining creative model-based learning with classical hands-on experimentation [22]. Visual representations are regarded as essential to understand complex (molecular) contents and especially models that are highly relevant for exemplification in teaching genetics [23].…”

Section: Teaching Genetics: the Role Of Outreach Laboratories And Modmentioning

confidence: 99%

“…A one-day module (270 min) on DNA structure for ninth graders at a university out-of-school lab was implemented by the same teacher. The hands-on learning activity was embedded in an inquiry-based setting where students worked in pairs, and used a workbook as a guide to encourage problem-solving as well as collaborative skills (for a detailed description of the module's phases see [22,34]). The contents of the lab day were adapted to follow the guidelines set by the Bavarian grammar school syllabus [54].…”

Section: Educational Interventionmentioning

confidence: 99%

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Comparing the Use of Two Different Model Approaches on Students’ Understanding of DNA Models

Mierdel

Bogner

2019

Education Sciences

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As effective methods to foster students’ understanding of scientific models in science education are needed, increased reflection on thinking about models is regarded as a relevant competence associated with scientific literacy. Our study focuses on the influence of model-based approaches (modeling vs. model viewing) in an out-of-school laboratory module on the students’ understanding of scientific models. A mixed method design examines three subsections of the construct: (1) students’ reasoning about multiple models in science, (2) students’ understanding of models as exact replicas, and (3) students’ understanding of the changing nature of models. There were 293 ninth graders from Bavarian grammar schools that participated in our hands-on module using creative model-based tasks. An open-ended test item evaluated the students’ understanding of “multiple models” (MM). We defined five categories with a majority of students arguing that the individuality of DNA structure leads to various DNA models (modelers = 36.3%, model viewers = 41.1%). Additionally, when applying two subscales of the quantitative instrument Students’ Understanding of Models in Science (SUMS) at three testing points (before, after, and delayed-after participation), a short- and mid-term decrease for the subscale “models as exact replicas” (ER) appeared, while mean scores increased short- and mid-term for the subscale “the changing nature of models” (CNM). Despite the lack of differences between the two approaches, a positive impact of model-based learning on students’ understanding of scientific models was observed.

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“…With the creative teaching structure, the motivation to finish difficult (thought) processes, work on science and learning increased, as did long-term learning performance. More information about the intervention design of Gen-ious is described in [39,40].…”

Section: Introductionmentioning

confidence: 99%

Full STEAM Ahead with Creativity

Conradty¹,

Sotiriou²,

Bogner³

2023

Pedagogy, Learning, and Creativity

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The integration of arts in science education (STEAM) aims to provide innovative activities to reach deeper learning levels and generally promote student engagement in (science) education. The European Horizon 2020 project CREATIONS with 16 partner institutions addresses this challenge with more than 100 initiatives over three years. All initiatives followed our STEAM guidelines based on the fundamental principles of responsible research and innovation (RRI). The positive effects of STEAM on cognition and motivation were evident in all initiatives with a sufficient empirical database. Besides the intention to integrate creativity, our study focused on flow that is experience of total immersion and exhilarating absorption in an activity that is experienced as effortlessly mastered. The productivity resulting from the self-rewarding creative rush makes flow particularly interesting. This chapter contributes to the open question of how flow is triggered with an exemplary meta-analysis of motivation and creativity scores of ten interventions ranging from complex projects at CERN to art-centred, play-based, laboratory-oriented projects or almost classical school initiatives. The regression analysis decoded self-efficacy as the crucial factor enabling the flow experience—which was demonstrated in this study for the first time, moreover, in a variety of age groups in the context of classroom activities.

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Simply InGEN(E)ious! How Creative DNA Modeling Can Enrich Classic Hands-On Experimentation

Cited by 7 publications

References 10 publications

Antiracist Opportunities in the Journal of Microbiology and Biology Education : Considerations for Diversity, Equity, and Inclusion

Antiracist Opportunities in the Journal of Microbiology and Biology Education : Considerations for Diversity, Equity, and Inclusion

Comparing the Use of Two Different Model Approaches on Students’ Understanding of DNA Models

Full STEAM Ahead with Creativity

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