The students will be learn about GMOs and their impact on society by watching a video, conducting research, and creating an opinion paper.

Gene mutations occur naturally through the DNA replication process with some results being fatal and others being helpful.  This lesson will explore the types of mutations that occur, the effect they have on DNA, and examples of diseases or conditions caused by the specific type of mutation.  Students will participate in a gallery walk to learn more about the types of mutations. 

The aim of the course has always been a practical one. We want to give students practice in performing the commonest techniques in molecular biology and genetic engineering as well as providing a good basic understanding of how the techniques worked. Though you won’t be doing the wet lab part of the course this semester, you will get some experience via simulations and other “lab exercises” and you will get plenty of experience in planning and designing constructs to answer biological questions. Part of our aim is to prepare students for a career in genetic engineering and this hasn’t changed.

Many times, gene mutations lead to some sort of genetic disease or disorder.  Through this lesson, students will explore a genetic disease, caused by a specific type of gene mutation (previously learned about) and present their findings to the class.   

This course will focus on understanding aspects of modern technology displaying exponential growth curves and the impact on global quality of life through a weekly updated class project integrating knowledge and providing practical tools for political and business decision-making concerning new aspects of bioengineering, personalized medicine, genetically modified organisms, and stem cells. Interplays of economic, ethical, ecological, and biophysical modeling will be explored through multi-disciplinary teams of students, and individual brief reports.

This course will assess the relationships among sequence, structure, and function in complex biological networks as well as progress in realistic modeling of quantitative, comprehensive, functional genomics analyses. Exercises will include algorithmic, statistical, database, and simulation approaches and practical applications to medicine, biotechnology, drug discovery, and genetic engineering. Future opportunities and current limitations will be critically addressed. In addition to the regular lecture sessions, supplementary sections are scheduled to address issues related to Perl, Mathematica and biology.

Word Count: 10668

(Note: This resource's metadata has been created automatically by reformatting and/or combining the information that the author initially provided as part of a bulk import process.)

Through six lesson/activity sets, students learn about the functioning of sensors, both human and robotic. In the activities, student groups use LEGO MINDSTORMS(TM) NXT robots and components to study human senses (sight, hearing, smell, taste, touch) in more detail than in previous units in the series. They also learn about the human made rotation, touch, sound, light and ultrasonic sensors. "Stimulus-sensor-coordinator-effector-response" pathways are used to describe the processes as well as similarities between human/animal and robotic equivalent sensory systems. The important concept of sensors converting/transducing signals is emphasized. Through assorted engineering design challenges, students program the LEGO robots to respond to input from various LEGO sensors. The overall framework reinforces the theme of the human body as a system with sensors that is, from an engineering perspective. PowerPoint® presentations, quizzes and worksheets are provided throughout the unit.

Four lessons related to robots and people present students with life sciences concepts related to the human body (including brain, nervous systems and muscles), introduced through engineering devices and subjects (including computers, actuators, electricity and sensors), via hands-on LEGO® robot activities. Students learn what a robot is and how it works, and then the similarities and differences between humans and robots. For instance, in lesson 3 and its activity, the human parts involved in moving and walking are compared with the corresponding robot components so students see various engineering concepts at work in the functioning of the human body. This helps them to see the human body as a system, that is, from the perspective of an engineer. Students learn how movement results from 1) decision making, such as deciding to walk and move, and 2) implementation by conveying decisions to muscles (human) or motors (robot).

Short Description:
This "textbook" is interactive, meaning that although each chapter has text, they also have interactive HTML5 content, such as quizzes, simulations, interactive videos, and images with clickable hotspots. Students receive instant feedback when they complete the interactive content, and therefore, can learn and check their understanding all in one place. The first unit introduces students to the nature of science, including scientific controversies, and information literacy, including how to analyze literature and identify stakeholders. Unit 2 is organismal biology, including carbon cycling and population growth, and unit 3 is molecular biology with a focus on gene expression.

Long Description:
This “textbook” is interactive, meaning that although each chapter has text, they also have interactive HTML5 content, such as quizzes, simulations, interactive videos, and images with clickable hotspots. Students receive instant feedback when they complete the interactive content, and therefore, can learn and check their understanding all in one place. I still consider this textbook to be fairly text-heavy and will continue to make it even more interactive content!

The image on the cover represents the creation of this book. I pulled most of the content from open resources, modified them, added questions, and now offer them for you to use!

I chose the content to align with two courses that I teach: environmental and organismal applications and biomedical applications. Unit 1 introduces students to science, which both courses use. Unit 2 covers content necessary for understanding conservation implications (the underlying theme of the course is de-extinction), and Unit 3 focuses on proteins so that students can understand the implications of modifying DNA (the underlying theme is CRISPR).

Please use this book as you see fit for your classes. I look forward to hearing how to make this book even more useful in the future!

Word Count: 27692

ISBN: 978-1-62610-106-7

(Note: This resource's metadata has been created automatically by reformatting and/or combining the information that the author initially provided as part of a bulk import process.)

Short Description:
This "textbook" is interactive, meaning that although each chapter has text, they also have interactive HTML5 content, such as quizzes, simulations, interactive videos, and images with clickable hotspots. Students receive instant feedback when they complete the interactive content, and therefore, can learn and check their understanding all in one place. The first unit introduces students to the nature of science, including scientific controversies, and information literacy, including how to analyze literature and identify stakeholders. Unit 2 is organismal biology, including carbon cycling and population growth, and unit 3 is molecular biology with a focus on gene expression.

Long Description:
This “textbook” is interactive, meaning that although each chapter has text, they also have interactive HTML5 content, such as quizzes, simulations, interactive videos, and images with clickable hotspots. Students receive instant feedback when they complete the interactive content, and therefore, can learn and check their understanding all in one place. I still consider this textbook to be fairly text-heavy and will continue to make it even more interactive content!

The image on the cover represents the creation of this book. I pulled most of the content from open resources, modified them, added questions, and now offer them for you to use!

I chose the content to align with two courses that I teach: environmental and organismal applications and biomedical applications. Unit 1 introduces students to science, which both courses use. Unit 2 covers content necessary for understanding conservation implications (the underlying theme of the course is de-extinction), and Unit 3 focuses on proteins so that students can understand the implications of modifying DNA (the underlying theme is CRISPR).

Please use this book as you see fit for your classes. I look forward to hearing how to make this book even more useful in the future!

Word Count: 34749

(Note: This resource's metadata has been created automatically by reformatting and/or combining the information that the author initially provided as part of a bulk import process.)

In this introduction to biotechnology's use in agriculture, learners will discuss history of the topic, model the fermentation process, and extract DNA in a lab activity.

This resource is a video abstract of a research paper created by Research Square on behalf of its authors. It provides a synopsis that's easy to understand, and can be used to introduce the topics it covers to students, researchers, and the general public. The video's transcript is also provided in full, with a portion provided below for preview:

"One key to good fish breeding is providing fish with the right food. That means getting the right-sized food. As fish larvae grow, so does the optimum size of their food. That’s a problem for certain species bred in fisheries. Fish raised on live feed face a gap in their feed size as larvae: at a certain stage, the plankton they eat become too small for maximum growth. This “food size gap” can affect the quality and value of fish raised for consumption. But researchers from Japan appear to have one solution: “supersizing” plankton with beams of heavy ions. Researchers from the RIKEN Nishina Center for Accelerator-Based Science generated high-powered beams of carbon and argon ions in the hopes of producing size-boosting mutations in rotifers, a phylum of plankton commonly fed to fish larvae. The tremendous amounts of energy carried by these beams, a couple hundred thousand times the amount a human might receive during a routine CT scan, was enough to alter the DNA in rotifer cells..."

The rest of the transcript, along with a link to the research itself, is available on the resource itself.

This course introduces experimental biochemical and molecular techniques from a quantitative engineering perspective. Experimental design, data analysis, and scientific communication form the underpinnings of this subject. Three discovery-based experimental modules focus on RNA engineering, protein engineering, and cell-biomaterial engineering.
This OCW site is based on the source OpenWetWare class Wiki, 20.109(S10): Laboratory Fundamentals of Biological Engineering.

This reading seminar examines land, water, food, and climate in a changing world, with an emphasis on key scientific questions about the connections between natural resources and food production. Students read and discuss papers on a range of topics, including water and land resources, climate change, demography, agroecology, biotechnology, trade, and food security. The readings are supplemented by short lectures that provide context and summarize main points. The seminar provides a broad perspective on one of the defining global issues of this century. Students consider scientific controversies as well as areas of general agreement and examine practical solutions for addressing critical problems.

Biotechnology is perhaps the most rapidly advancing area in science today. The Advances in Biotechnology volume has been created to provide language teachers with resources about breakthroughs in biotechnology. Each chapter of the volume highlights one aspect of research in the field of DNA and genetics along with its applications to and implications for society. The chapters feature relevant background information on each topic, interactive and communicative classroom activities, and a list of related print and Internet resources that will allow teachers to expand the lesson further.

This course is the first in a three-course sequence that introduces biology in preparation for advanced study in areas of biological science such as medicine, dentistry, cell biology, microbiology, or veterinary medicine. Biol& 211 introduces students to cellular structure and function. Major topics studied include: energy capture and utilization, cellular reproduction, inheritance, genetic mutation, protein synthesis, gene expression, and biotechnology.

This kit explores how sustainability within the Finger Lakes region of New York has been presented in the media with a particular focus on issues related to food, water and agriculture. Each of the seven lessons integrates media literacy and critical thinking with key knowledge and concepts related to sustainability. This kit is a companion to the nineteen-lesson collection, Media Constructions of Sustainability: Food, Water and Agriculture.

This kit explores how sustainability has been presented in the media with a particular focus on issues related to food, water and agriculture. Each of the 19 lessons integrates media literacy and critical thinking into lessons about different aspect of sustainability. Constant themes throughout the kit include social justice, climate change, energy, economics and unintended consequences.

Students design systems that use microbes to break down a water pollutant (in this case, sugar). They explore how temperature affects the rate of pollutant decomposition.