This video lesson shows students that math can play a role in understanding how an infectious disease spreads and how it can be controlled. During this lesson, students will see and use both deterministic and probabilistic models and will learn by doing through role-playing exercises. The primary exercises between video segments of this lesson are class-intensive simulation games in which members of the class 'infect' each other under alternative math modeling assumptions about disease progression. Also there is an occasional class discussion and local discussion with nearby classmates.

Learn how some animals eat other plants and animals to survive, and create a food chain. For more educational videos and games please visit www.turtlediary.com

Comprehensive curriculum/unit to teach how food systems affect climate change. Strong use of real data is embedded throughout. Full lessons, mini-lessons, and short videos are presented.

In this seminar your will experience how the use of polymers is a daily occurrence and compare the processes of how polymers are built for biological systems.  You will create a field guide to the biological macromolecules and their respective monomers.StandardsBIO.A.2.2.2 Describe how biological macromolecules form from monomers.BIO.A.2.2.3 Compare and contrast the structure and function of carbohydrates, lipids, proteins, and nucleic acids in organisms.

A diverse collection of lower Cretaceous (Albian) fossils is featured on this site. Fossil photos, illustrations and information about each suborder are provided for an array of fossil groups. Specific fossil groups include Ammonoidea, Bivalvia, Cephalopoda, Cnidaria (Corals), Echinodermata, Fish, Foraminifera, Gastropoda, Ostracoda, and Scaphopoda. Short discussions of United Kingdom geology, Albian stratigraphy, geologic time and fossil imaging techniques are also included.

An adaptation of OpenStax Biology and OpenStax Concepts of Biology from Greenfield Community College. in this version, we've curated content from both open textbooks to create a version suitable for an intro biology class in a community college, which frequently includes both biology majors and students taking the course as part of a general education curriculum.

Short Description:
Foundations of Biomedical Science: Quantitative Literacy Theory and Problems is designed to help students develop the fundamental mathematical and quantitative literacy required to navigate and interpret evidence-based Biomedical data. This will provide students with the skills and confidence to habitually question any quantitative data they come across and to use these skills to make informed judgements regarding their veracity.

Long Description:
Modern Biomedicine is evidence-based, which means it is underpinned by quantitative data. Recent technological advances have led to Biomedicine (and Biology in general) becoming more “data driven” and hence more quantitative and predictive. Hence, now more than ever, an understanding of quantitative data is crucial for students of Biomedical disciplines.

Foundations of Biomedical Science: Quantitative Literacy Theory and Problems is designed to help students develop the fundamental mathematical and quantitative literacy required to navigate and interpret evidence-based Biomedical data. This ebook is divided into short chapters, each containing a concise summary of: theory provided through a Biomedical context authentic worked examples, problem sets and solutions further extension and application of the theory.

These chapters build to provide students with the skills and confidence to habitually question any quantitative data they come across and to use these skills to make informed judgements regarding their veracity.

Word Count: 69830

ISBN: 978-0-6484681-8-9

(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.)

Are you interested in investigating how nature engineers itself? How engineers copy the shapes found in nature (“biomimetics”)? This Freshman Seminar investigates why similar shapes occur in so many natural things and how physics changes the shape of nature. Why are things in nature shaped the way they are? How do birds fly? Why do bird nests look the way they do? How do woodpeckers peck? Why can’t trees grow taller than they are? Why is grass skinny and hollow? What is the wood science behind musical instruments? Questions such as these are the subject of biomimetic research and they have been the focus of investigation in this course for the past three years.

Ready to find out how plants are grown and function? Take a fantastic voyage through plants. From Growing to Biology: Plants 1e brings the latest information for understanding of traditional and modern plant growing, form, and production. Topics covered in 30 chapters include concise and up-to-date ‘big picture’ infographics, student learning outcomes (SLOs), key vocabulary, assessment, as well as identification of 120 species, and more. Moreover, author Dr. G. Hacisalihoglu emphasizes on leaning concepts, binding those concepts together with visuals approach to make learning faster and more memorable.

From Growing to Biology: Plants 1e is packed full of horticultural information that is ideal for both academia and industry growers. It is basic enough that if you are just getting started learning plants, you will be able to catch up. Always remember that practice makes permanent and keep going to take your learning plant bio to new levels.

This illustrated guide to a grasshopper's head is designed to help students recognize and learn the many parts found on an insect's head. The single Web page, which can be easily printed for use at field sites or in the lab, also includes a short description for the following labeled parts: ocellus compound eye antenna gena frons clypeus mandible labrum labium palps.

Leaders in the field of biological diversity present an overview of emergent issues in biodiversity, from the surrounding flora and fauna to the genes deep within us. (117 minutes)

Dean Kim Barrett hosts eminent respiratory physiologist John West in a discussion of his storied career and research experiences. (58 minutes)

For more than two decades J. Craig Venter and his research teams have been pioneers in genomic research. Regarded as one of the leading scientist of the 21st century, Venter discusses how he is applying tools and techniques developed to sequence the human genomes to discover new genes of microbes from around the world. (57 minutes)

This video segment adapted from NOVA scienceNOW shows how the common wood frog freezes solid every winter, an adaptation that allows the organism to survive the cold winter.

In this seminar students construct graphic organizers to make sense of the profuse amount of concept specific vocabulary terms as they relate to the structure and function of the 4 biomacromolecules.  They will collect data as they test common foods for the presence of these 4 organic molecules in a virtual lab.StandardsBIO.A.2.2.2 Describe how biological macromolecules form from monomers.BIO.A.2.2.3 Compare and contrast the structure and function of carbohydrates, lipids, proteins, and nucleic acids in organisms.

This activity is a classroom and field activity in which students record observations of birds in their natural habitat and make connections between the structure and function of the bird feet.

Word Count: 222624

(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.)

Long Description:
An introduction to biology intended for non-science majors. Focus areas include chemical foundations, cell structure and division, genetics, and evolution.

Word Count: 120840

(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.)

The goal of this initiative is to improve students' learning of the subject while developing their Inquiry and Problem-Solving competencies as well as their numeracy, written, digital and oral communication abilities. A flipped-class approach will be taken to present different topics ahead of the practical laboratory experiences. Topics will be presented with PowerPoints and/or videos posted on Blackboard. Students will be given a low stakes quiz at the beginning of each laboratory session to assess their knowledge and understanding of the posted material. A research project, introduced at the beginning of the semester, will be used as the backbone to integrate inquiry and problem-solving competencies to the laboratories. Each laboratory will explore a question/aspect outlined in the research project; students will be expected to work in pre-assigned groups and present individual written outputs, data, and analysis at the end of each laboratory session. Students will be expected to compile their results obtained during the semester, and make a digital/oral presentation at the end of the term. Students will collect background information and complete four written assignments; students will receive feedback on these assignments to allow for improvements and successful completion of the final presentations. Each individual student will also be required to write three laboratory reports. Collaborative work with group members will be essential for successful learning using an Inquiry and problem solving approach, although written reports will be marked individually, per the guidelines given in the assignments. The syllabus for the lecture component of these sections is identical to the syllabus of the standard versions of this course; the grading procedures for the laboratory component of the course are modified as described in the grading policy below.
LaGuardia's Core Competencies and Communication Abilities
Main Course Learning Objectives:
This course is an integrated two-semester laboratory-based sequence, stressing major concepts of biology designed to assist the student in relating these concepts to the environment. The scientific method of thinking and the experimental approach will be stressed. Among the topics studied are: SCB201 Cellular and molecular basis of life, heredity, and the evolution of life.