The document describes a newly developed undergraduate bioinformatics course at the University of Texas at Tyler. The course teaches students how to integrate biological knowledge with computational methods to handle and analyze large-scale biological data. Students learn technical skills like computer coding and statistical analysis in labs, and are assessed through projects rather than exams to focus on applying their skills. The course aims to help students develop practical and transferable competencies for various professions.
Z Score,T Score, Percential Rank and Box Plot Graph
Developing an undergraduate bioinformatics course
1. Scientfc thinking with computatonal skills
Developing an undergraduate bioinformatcs course
Kate L Hertweck, Ph.D, Department of Biology, The University of Texas at Tyler
ABSTRACT
A challenge for undergraduate science educators is
meetng increasing demands for students to handle,
analyze, and interpret large-scale biological data.
Bioinformatcs (BIOL 4306/4106) is a newly developed
course being taught in spring 2015 through the
Department of Biology. During the lecture and lab,
students are taught how to integrate biological content
knowledge with computatonal methods. The use of
technology and focus on critcal scientfc thinking make
the class challenging but tractable for students from a
variety of educatonal backgrounds. Assessments are
designed to help students develop practcal,
transferable skills they can apply to a variety of
professions.
IMPLEMENTATION
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Lecture highlights concepts and theory related to
analysis of large biological datasets, like from
genomic sequencing projects.
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Lab focuses on technical skills, like implementng
computer code and statstcal analyses, to solve
problems.
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Assessment is based on homework and projects,
rather than exams, to focus on applicaton of skills.
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All materials developed for lab are publicly available:
htps://github.com/BioinformatcsSpring2015
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Another new class, Bioinformatcs for Research, will
be ofered in Fall 2015 to assist Biology graduate
students in performing scientfc research.
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Describe the scope of bioinformatcs research and
applicatons
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Design and implement bioinformatcs pipelines to answer
pre-defned questons from a variety of biological
disciplines
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Validate results from bioinformatcs algorithms using
hypothesis testng, correctng for multple comparisons,
etc.
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Characterize the limitatons of data to answer questons
of interests
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Obtain resources to learn new languages and algorithms
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Code basic scripts to accomplish the goals above
COURSE OBJECTIVES COURSE CURRICULUM SUMMARY
Bioinformatcs Framework: fundamental skills
and knowledge for analyzing biological data
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Data in biology
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Workfows and pipelines
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Statstcal inference
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Data visualizaton
Applied Bioinformatcs: general topics that apply
learning from Bioinformatcs Framework
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Sequence searching
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Phylogenetcs and clustering
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Genome assembly
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Comparatve genomics
PRE-CLASS SURVEY RESULTS
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All students were biology majors
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All students agreed (strongly or moderately) that
they wanted to improve their data analysis
capabilites
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Some students had previous experience with
computer programming.
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Most students believed computatonal skills
would be important to their future careers
BIOINFORMATICS
Software
DNA sequences Genomic data
Computer programming
Statistics and
visualization