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Biomimicry: Natural Designs
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Students learn about biomimicry and how engineers often imitate nature in the design of innovative new products. They demonstrate their knowledge of biomimicry by practicing brainstorming and designing a new product based on what they know about animals and nature.

Author:
Malinda Schaefer Zarske
Katherine Beggs
Integrated Teaching and Learning Program,
Denise Carlson
Biotechnology
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This course will introduce the student to the major concepts of biotechnology. The student will discuss genetic engineering of plants and animals and the current major medical, environmental, and agricultural applications of each. There are also a variety of topics that this course will cover after ranging from nanobiotechnology to environmental biotechnology. Upon successful completion of this course, the student will be able to: identify and describe the fields of biotechnology; compare and contrast forward and reverse genetics and the way they influence biodiversity; compare and contrast systemic studies of the genome, transcriptome, and proteome; explain how genome projects are performed, and discuss the completion and the information processing in these projects; describe and explain the principles of existing gene therapies; design strategies that support genetic counseling; explain and analyze DNA fingerprints, and compare DNA fingerprints to non-DNA biometrics; describe and compare bioremediation technologies in air, water, and soil; design strategies for generating genetically modified organisms, and discuss ethical concerns; discuss emerging fields in biotechnology. (Biology 403)

Birds' Bills
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Students compare and contrast birds' bills and compare them to household items.

Author:
Vick, Sharon
Sharon Vick
Sharon J. Vick, Stevens Elementary School, Dawson, MN
Birds:  How Do We Increase the Bird Population at our School?
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This activity is a field investigation of the bird population in the schoolyard and how the students will plan to attract more birds.

Author:
Lori Huisenga
Lori Huisenga, Lincoln Elementary School, Owatonna, MN. A shared idea from the Savage-Prior Lake School.
Blood: The Stuff of Life
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The purpose of this lesson is to teach students about blood and its components while instilling an appreciation of its importance for survival. The lesson takes a step-by-step approach to determining the recipe for blood while introducing students to important laboratory techniques like centrifugation and microscopy, as well as some diseases of cell types found in blood. It also highlights the importance of donating blood by explaining basic physiological concepts and the blood donation procedure.

Author:
Melis Anahtar
Botany
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In this course, you will learn the basics of plant biology. The student will begin with plant anatomy, learning the names and functions of all of the parts of a plant, then move on to plant physiology, where you will learn about photosynthesis, growth, and reproduction. Next, the student will study plant evolution according to the fossil record and examine the diversity of plant life in existence today and how that diversity impacts global ecology. Upon successful completion of this course, the student will be able to: identify and describe the functions of the different cells, tissues, and organs that make up a plant; describe the major life processes in plants (photosynthesis, respiration, transpiration, growth and development, and reproduction) at the tissue, organ, cellular, and molecular level; explain the history and evolution of plants on earth; discuss plant diversity and identify the major characteristics of plant phylogenetic divisions; explain how plants fit into the global ecological system and why they are essential for life on earth. (Biology 306)

Brine Shrimp Inquiry
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This classroom lab is a guided practice for inquiry using brine shrimp as the subject to be investigated.

Author:
Diane Hoffman
A Bug's Life: Under A Rock!
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This activity is a biology lab investigation where students create habitats to observe decomposers in a controlled setting.

Author:
Joan McKinnon
Cancer Biology
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This course will cover the origins of cancer and the genetic and cellular basis for cancer. It will examine the factors that have been implicated in triggering cancers; the intercellular interactions involved in cancer proliferation; current treatments for cancer and how these are designed; and future research and treatment directions for cancer therapy. Upon successful completion of this course, the student will be able to: explain how the perception of cancer and theories of its causes have changed throughout history because of important discoveries made by scientists, researchers, and physicians; summarize the importance of understanding cell biology in the study of cancer, its causes, it progression, and its treatment; outline the transcription and translation processes used to convert DNA into proteins and what changes occur that convert proto-oncogenes into oncogenes and lead to unchecked cell growth and cancer; compare and contrast the mechanisms by which activation of oncogenes, loss of tumor suppressors, loss of cell cycle checkpoints, and development of faulty DNA repair lead to cancer; describe the various cancer prevention mechanisms including risk assessment, screening, and lifestyle and environmental modification; list the past, current, and future cancer treatments and the mechanism by which these target cancer causing cells. (Biology 404)

Cancer Biology: From Basic Research to the Clinic, Fall 2004
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CC BY-NC-SA
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Seminar covering topics of current interest in biology. Includes reading and analysis of research papers and student presentations. Contact Biology Education Office for topics. This course is one of many Advanced Undergraduate Seminars offered by the Biology Department at MIT. These seminars are tailored for students with an interest in using primary research literature to discuss and learn about current biological research in a highly interactive setting. In 1971, President Nixon declared the "War on Cancer," but after three decades the war is still raging. How much progress have we made toward winning the war and what are we doing to improve the fight? Understanding the molecular and cellular events involved in tumor formation, progression, and metastasis is crucial to the development of innovative therapy for cancer patients. Insights into these processes have been gleaned through basic research using biochemical, molecular, and genetic analyses in yeast, C. elegans, mice, and cell culture models. We will explore the laboratory tools and techniques used to perform cancer research, major discoveries in cancer biology, and the medical implications of these breakthroughs. A focus of the class will be critical analysis of the primary literature to foster understanding of the strengths and limitations of various approaches to cancer research. Special attention will be made to the clinical implications of cancer research performed in model organisms and the prospects for ending the battle with this devastating disease.

Subject:
Biology
Life Science
Material Type:
Full Course
Textbook
Author:
Haigis, Kevin
Kim, Carla
Date Added:
01/01/2004
Cell Biology
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This course will present the student with a detailed overview of a cell's main components and functions. The course is roughly organized into four major areas: the cell membrane, cell nucleus, cell cycle, and cell interior. The student will approach most of these topics straightforwardly, from a molecular and structural point of view. Upon completion of this course, the student will be able to: explain what a eukaryotic cell is, identify the components of the cell, and describe how a cell functions; explain how cell membranes are formed; identify the general mechanisms of transport across cell membranes; list the different ways in which cells communicate with one another--specifically, via signaling pathways; define what the extracellular matrix is composed of in different cells and how the extracellular matrix is involved in forming structures in specific tissues; list the components of the cell's cytoskeleton and explain how the cytoskeleton is formed and how it directs cell movements; explain the fundamentals of gene expression and describe how gene expression is regulated at the protein level; define and explain the major cellular events involved in mitosis and cytokinesis; identify the major cellular events that occur during meiosis; describe the eukaryotic cell cycle and identify the events that need to occur during each phase of the cell cycle; identify all of the major organelles in eukaryotic cells and their respective major functions. (Biology 301)

Cell Biology, Spring 2007
Conditional Remix & Share Permitted
CC BY-NC-SA
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Biology of cells of higher organisms: structure, function, and biosynthesis of cellular membranes and organelles; cell growth and oncogenic transformation; transport, receptors and cell signaling; the cytoskeleton, the extracellular matrix, and cell movements; chromatin structure and RNA synthesis.

Subject:
Biology
Life Science
Material Type:
Full Course
Textbook
Author:
Orr-Weaver, Terry
Date Added:
01/01/2007
Cell Biology: Structure and Functions of the Nucleus, Spring 2010
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The goal of this course is to teach both the fundamentals of nuclear cell biology as well as the methodological and experimental approaches upon which they are based. Lectures and class discussions will cover the background and fundamental findings in a particular area of nuclear cell biology. The assigned readings will provide concrete examples of the experimental approaches and logic used to establish these findings. Some examples of topics include genome and systems biology, transcription, and gene expression.

Author:
Sharp, Phillip
Young, Richard
Cellular Garbage Disposal: Misfolded Proteins in Normal Biology and Human Disease, Fall 2011
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The endoplasmic reticulum (ER) orchestrates different cellular processes by which proteins are synthesized, correctly folded, modified and ultimately transported to their final destinations. As part of this crucial biosynthetic process, proteins that are not properly folded and consequently detrimental to normal cellular function are constantly generated. A common signature of many neurodegenerative diseases, including Alzheimer's and Parkinson's, is accumulation and deposition of misfolded proteins that arise when the ability of cells to deal with the burden of misfolded proteins is compromised. In this course, we will explore how the ER quality control machinery ensures that only properly assembled proteins exit the ER while distinguishing between nascent proteins en route to their biologically active folded state from those that are terminally misfolded.

Author:
Sanyal, Sumana
Changes in a Monarch's Life Cycle
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This activity will include the students observing the monarch life cycle inside the classroom, a field experience observing monarch life on a milkweed plant and drawing it, and back in the classroom students will make a pop-up book of the monarch's life cycle with a short description on each page.

Classification, Natural Kinds, and Conceptual Change: Race as a Case Study, Spring 2004
Conditional Remix & Share Permitted
CC BY-NC-SA
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This course will consider the claim that there is no such thing as race, with a particular emphasis on the question whether races should be thought of as natural kinds: is our concept of race a natural kind concept? Is the term 'race' a natural kind term? If so, is Appiah right to conclude that there are no races? How should one go about "analyzing" the concept of race?

Subject:
Arts and Humanities
Biology
Life Science
Philosophy
Material Type:
Full Course
Textbook
Author:
Haslanger, Sally
Date Added:
01/01/2004
Classifying Animals by Appearance Versus DNA Sequence
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The topic of this video module is how to classify animals based on how closely related they are. The main learning objective is that students will learn how to make phylogenetic trees based on both physical characteristics and on DNA sequence. Students will also learn why the objective and quantitative nature of DNA sequencing is preferable when it come to classifying animals based on how closely related they are. Knowledge prerequisites to this lesson include that students have some understanding of what DNA is and that they have a familiarity with the base-pairing rules and with writing a DNA sequence.

Author:
Megan E. Rokop
Classify the Trees/Leaves
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This activity is a field investigation where students gather leaves from various trees on school property, interpret findings, name tree and leaves, journal activity and develop a new "aha" for nature!

Author:
Mary Walsh