Developing and applying computational resources for biochemistry education

Craig, P.

doi:10.1002/bmb.21347

Cited by 4 publications

(3 citation statements)

References 22 publications

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“…Cause the teaching of biochemistry mostly involves interdisciplinary themes, it is really a difficult subject for both teachers and students [2,3]. Previously, research on the reform of biochemistry teaching mainly focused on online teaching [4], distance education [5], PBL(Problem based learning), TBL(Team Based Learning) or CBL(Case Study Based Learning) teaching model research [6][7][8], the construction of a framework for cultivating students' biochemical literacy [9], or the development of computing resources in biochemistry education and applications [10]. There was a lack of exploration of the path of combining humanities education and subject education.…”

Section: Introductionmentioning

confidence: 99%

Research on the Path of Aiding Integrating Excellent Traditional Chinese Culture into Biochemistry Teaching Curriculum with the Artificial Intelligence Technologies

Jiachen Liu

2024

jes

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Traditional culture has profound connotation and great inclusiveness. Incorporating traditional culture into biochemistry education not only boosts students' enthusiasm and attentiveness but also expands their analytical viewpoints. With the help of artificial intelligence technology, interweaving scientific and cultural wisdom, we can better promote our ancient traditions and instill a deep sense of national pride in our students. The article delves into the backdrop of merging Chinese exemplary traditional culture with the biochemistry curriculum. It further investigates the challenges of intensifying the instruction of this esteemed culture and the considerations when utilizing Chinese traditional values to enhance biochemistry education. On this basis, the article highlights the practical rationale for weaving Chinese exemplary traditional culture into the biochemistry curriculum, and briefly discusses the possible ways to improve the teaching effect of the course with the help of artificial intelligence technology, in order to promote the profound synergy between the three and thus promote the development of the biochemistry education framework.

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Section: Introductionmentioning

confidence: 99%

Research on the Path of Aiding Integrating Excellent Traditional Chinese Culture into Biochemistry Teaching Curriculum with the Artificial Intelligence Technologies

Jiachen Liu

2024

jes

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“…The PDB resource is essential to multiple communities: It provides a permanent and expertly curated resource for structural biologists to archive and disseminate their work, provides mechanisms to ensure reproducibility in the structural biology literature, and makes biomolecular structures freely and easily available to a wide community of researchers across scientific disciplines 1 . PDB data are also broadly used in science, technology, engineering, and mathematics (STEM)‐related education, including textbook illustrations, coursework, and learning activities 2–11 . Images of 3D PDB structures are frequently used to tell scientific stories in mainstream news media, starting with the familiar double helix of DNA to more recent examples of CRISPR and coronavirus 12…”

Section: Introductionmentioning

confidence: 99%

PDB‐101: Educational resources supporting molecular explorations through biology and medicine

et al. 2021

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The Protein Data Bank (PDB) archive is a rich source of information in the form of atomic‐level three‐dimensional (3D) structures of biomolecules experimentally determined using macromolecular crystallography, nuclear magnetic resonance (NMR) spectroscopy, and electron microscopy (3DEM). Originally established in 1971 as a resource for protein crystallographers to freely exchange data, today PDB data drive research and education across scientific disciplines. In 2011, the online portal PDB‐101 was launched to support teachers, students, and the general public in PDB archive exploration (http://pdb101.rcsb.org). Maintained by the Research Collaboratory for Structural Bioinformatics PDB, PDB‐101 aims to help train the next generation of PDB users and to promote the overall importance of structural biology and protein science to nonexperts. Regularly published features include the highly popular Molecule of the Month series, 3D model activities, molecular animation videos, and educational curricula. Materials are organized into various categories (Health and Disease, Molecules of Life, Biotech and Nanotech, and Structures and Structure Determination) and searchable by keyword. A biennial health focus frames new resource creation and provides topics for annual video challenges for high school students. Web analytics document that PDB‐101 materials relating to fundamental topics (e.g., hemoglobin, catalase) are highly accessed year‐on‐year. In addition, PDB‐101 materials created in response to topical health matters (e.g., Zika, measles, coronavirus) are well received. PDB‐101 shows how learning about the diverse shapes and functions of PDB structures promotes understanding of all aspects of biology, from the central dogma of biology to health and disease to biological energy.

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“…Similarly, the traditional educational divisions between engineering, computational, physical science, and biological curricula have impeded communication between these silos and raised barriers both to the use of simulations by biologists and the effective understanding of biological needs and design of tools for biological applications by engineers [ 5 , 43 ]. There has been an ongoing effort to incorporate quantitative or computational content into undergraduate biology courses [ 1 , 4 , 9 , 14 , 42 , 53 ]. Similarly, there are several reports of reforms to provide greater life sciences disciplinary content to engineering students [ 18 , 24 , 52 ].…”

Section: Introductionmentioning

confidence: 99%

Supporting Computational Apprenticeship Through Educational and Software Infrastructure: A Case Study in a Mathematical Oncology Research Lab

Madamanchi¹,

Thomas

Magana³

et al. 2021

PRIMUS

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There is growing awareness of the need for mathematics and computing to quantitatively understand the complex dynamics and feedbacks in the life sciences. Although several institutions and research groups are conducting pioneering multidisciplinary research, communication and education across fields remain a bottleneck. The opportunity is ripe for using education research-supported mechanisms of cross-disciplinary training at the intersection of mathematics, computation, and biology. This case study uses the computational apprenticeship theoretical framework to describe the efforts of a computational biology lab to rapidly prototype, test, and refine a mentorship infrastructure for undergraduate research experiences. We describe the challenges, benefits, and lessons learned, as well as the utility of the computational apprenticeship framework in supporting computational/math students learning and contributing to biology, and biologists in learning computational methods. We also explore implications for undergraduate classroom instruction and cross-disciplinary scientific communication.

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Developing and applying computational resources for biochemistry education

Cited by 4 publications

References 22 publications

Research on the Path of Aiding Integrating Excellent Traditional Chinese Culture into Biochemistry Teaching Curriculum with the Artificial Intelligence Technologies

Research on the Path of Aiding Integrating Excellent Traditional Chinese Culture into Biochemistry Teaching Curriculum with the Artificial Intelligence Technologies

PDB‐101: Educational resources supporting molecular explorations through biology and medicine

Supporting Computational Apprenticeship Through Educational and Software Infrastructure: A Case Study in a Mathematical Oncology Research Lab

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