Anthropology is the study of humanity, in all its biological and cultural aspects, past and present. It is a four-field discipline comprised of biological anthropology, cultural anthropology, archaeology, and linguistic anthropology. The focus of this book is biological anthropology, which explores who we are from biological, evolutionary, and adaptive perspectives.

Chapter 1: Introduction to Biological Anthropology
Chapter Two: Evolution
Chapter 3: Introduction to Molecular Biology and Genetics
Chapter 4: Forces of Evolution
Chapter 5: Meet the Living Primates
Chapter 6: Primate Ecology and Behavior
Chapter 7: Understanding the Fossil Context
Chapter 8: Primate Evolution
Chapter 9: Early Hominins
Chapter 10: Early Members of the Genus Homo
Chapter 11: Archaic Homo
Chapter 12: Modern Homo sapiens
Chapter 13: Race and Human Variation
Chapter 14: Human Variation: An Adaptive Significance Approach
Chapter 15: Bioarchaeology and Forensic Anthropology
Chapter 16: Contemporary Topics: Human Biology and Health
Appendix A: Osteology
Appendix B: Primate Conservation
Appendix C: Human Behavioral Ecology

Reviews available here: https://open.umn.edu/opentextbooks/textbooks/explorations-an-open-invitation-to-biological-anthropology-shook

Powerpoint slides here: https://drive.google.com/drive/folders/1wp4NDnXBiWhhsN-cAXQlIteS8PeOx9pB

Request access for the test bank: https://docs.google.com/forms/d/e/1FAIpQLSeEwpBLlsu4dWx-49UsF2lCPWfzubdQNAyzxdS7EjA2AMPI3w/viewform

Emotions play a crucial role in our lives because they have important functions. This module describes those functions, dividing the discussion into three areas: the intrapersonal, the interpersonal, and the social and cultural functions of emotions. The section on the intrapersonal functions of emotion describes the roles that emotions play within each of us individually; the section on the interpersonal functions of emotion describes the meanings of emotions to our relationships with others; and the section on the social and cultural functions of emotion describes the roles and meanings that emotions have to the maintenance and effective functioning of our societies and cultures at large. All in all we will see that emotions are a crucially important aspect of our psychological composition, having meaning and function to each of us individually, to our relationships with others in groups, and to our societies as a whole.

An integrated course stressing the principles of biology. Life processes are examined primarily at the organismal and population levels. Intended for students majoring in biology or for non-majors who wish to take advanced biology courses.

General Biology is intended to leave the student with an integrated view of the living world including the nature of sciences, evolution of biological organization, composition and organization of living substances, metabolism, control, reproduction, heredity and ecological relationships. This class meets the A.A. degree lab science requirement in the State of Washington.Login: guest_oclPassword: ocl

Genetics is the branch of biology that studies the means by which traits are passed on from one generation to the next and the causes of similarities and differences between related individuals. In this course, the student will take a close look at chromosomes, DNA, and genes. The student will learn how hereditary information is transferred, how it can change, how it can lead to human disease and be tested to indicate disease, and much more. Upon successful completion of this course, students will be able to: give a brief synopsis of the history of genetics by explaining the fundamental genetic concepts covered in this course as they were discovered through time; identify the links between Mendel's discoveries (often represented by Punnett squares) with mitosis and meiosis, dominance, penetrance, and linkage; recognize the role of simple probability in genetic inheritance; apply advanced genetic concepts, including genetic mapping and transposons, to practical applications, including pedigree analysis and corn kernel color; identify the cause behind several genetic diseases currently prevalent in society (such as color blindness and hemophilia) and recognize the importance of genetic illness throughout history; compare and contrast advanced concepts of chromosomal, bacterial, human, and population genetics; recognize the similarities and differences between nuclear, chloroplast, and mitochondrial DNA; describe the fundamentals of population genetics, calculate gene frequencies in a give scenario, predict future gene frequencies over future generations, and define the role of evolution in gene frequency shift over time; recall, analyze, synthesize, and build on the foundational material to then learn the cutting-edge technological advances in genetics, including genomics, population and evolutionary genetics, and QTL mapping. (Biology 305)

Where did we come from? What were our ancestors like? Why do we differ from other animals? How do scientists trace and construct our evolutionary history? The History of Our Tribe: Hominini provides answers to these questions and more. The book explores the field of paleoanthropology past and present. Beginning over 65 million years ago, Welker traces the evolution of our species, the environments and selective forces that shaped our ancestors, their physical and cultural adaptations, and the people and places involved with their discovery and study. It is designed as a textbook for a course on Human Evolution but can also serve as an introductory text for relevant sections of courses in Biological or General Anthropology or general interest. It is both a comprehensive technical reference for relevant terms, theories, methods, and species and an overview of the people, places, and discoveries that have imbued paleoanthropology with such fascination, romance, and mystery.

Examines the dynamic interrelations among physical and behavioral traits of humans, environment, and culture to provide an integrated framework for studying human biological evolution and modern diversity. Topics include issues in morphological evolution and adaptation; fossil and cultural evidence for human evolution from earliest times through the Pleistocene; evolution of tool use and social behavior; modern human variation and concepts of race. Includes study of stone artifacts and fossil specimens.

This course describes biological changes that happen on a very large scale, across entire populations of organisms and over the course of millions of years, in the form of evolution and ecology. Upon successful completion of this course, students will be able to: Use their understanding of Mendelian genetics and patterns of inheritance to predict genotypes and phenotypes of offspring or work backwards to identify the genotypes and phenotypes of a parental generation; Distinguish between inheritance patterns that involve autosomal vs. sex-linked traits and identify the respective consequences of each type of inheritance; Identify what distinguishes DarwinĺÎĺĺÎĺs theory of evolution from other arguments that attempt to explain diversity across species and/or many generations; Identify which of many types of natural selection is acting on a particular population/species; Identify which of many types of sexual selection is acting on a particular population/species; Identify the factors that alter the frequencies of alleles in populations over time and describe the effects of these factors on populations; Recognize, read, and create phylogenies and cladograms, using them to explain evolutionary relationships; Determine the ecological interactions affecting a particular community and identify the effects of specific relationships (e.g. symbiosis, competition) on species within that community; Distinguish between world biomes in terms of their climate, nutrient cycles, energy flow, and inhabitants; Use their knowledge of nutrient cycles and energy flow to estimate the effect that changes in physical or biological factors would have on a particular ecosystem. (Biology 102; See also: Psychology 204)

This lab course supplements ĺÎĺĺĺŤIntroduction to Evolutionary Biology and EcologyĄ_ĺĺö. Although it does not replicate a true lab experience, it does encourage greater familiarity with scientific thinking and techniques, and will enable exploration of some key principles of evolutionary biology and ecology. This lab supplement focuses on visual understanding, application, and practical use of knowledge. In each unit, the student will work through tutorials related to important scientific concepts and then will be asked to think creatively about how that knowledge can be put to practical or experimental use. Upon successful completion of this lab supplement, the student will be able to: Display an understanding of Mendelian inheritance as applied to organisms in virtual experiments; Describe the process of natural selection and understand how it will alter populations over generations and under a variety of selection pressures; Understand how the process of speciation is affected by isolation and selection pressures; Understand predator-prey dynamics under a variety of ecological conditions; Distinguish between biomes in terms of their structure/climates as well as the types and diversity of organisms that inhabit them. (Biology 102 Laboratory)

Though biology as we know it today is a relatively new field, we have been studying living things since the beginning of recorded history. This introductory course in biology starts at the microscopic level, with molecules and cells, then moves into the specifics of cell structure and behavior. Upon successful completion of this course, students will be able to: Describe in general terms how life began on Earth; Identify early scientists that played important roles in furthering our understanding of cellular life; Describe the characteristics that define life; List the inorganic and organic molecules that are necessary for life; List the structure and function of organelles in animal and plant cells; List the similarities and differences between animal and plant cells; Describe the reactions in photosynthesis; Explain how the different photosynthetic reactions are found in different parts of the chloroplast; Describe the sequence of photosynthetic reactions; Explain the use of products and the synthesis of reactants in photosynthesis; Explain how protein is synthesized in eukaryotic cells; Describe the similarities and differences between photosynthesis and aerobic respiration; List the reactions in aerobic respiration; Explain the use of products and the synthesis of reactants in aerobic respiration; Describe the similarities and differences between anaerobic and aerobic respiration. (Biology 101; See also: Psychology 203)

The MIT Biology Department core courses, 7.012, 7.013, and 7.014, all cover the same core material, which includes the fundamental principles of biochemistry, genetics, molecular biology, and cell biology. 7.013 focuses on the application of the fundamental principles toward an understanding of human biology. Topics include genetics, cell biology, molecular biology, disease (infectious agents, inherited diseases and cancer), developmental biology, neurobiology and evolution.Biological function at the molecular level is particularly emphasized in all courses and covers the structure and regulation of genes, as well as, the structure and synthesis of proteins, how these molecules are integrated into cells, and how these cells are integrated into multicellular systems and organisms. In addition, each version of the subject has its own distinctive material.  

Oceanography will present the ocean in an historical and geographical context.We will examine physical and exploration ocean science in a holistic manner. Origins and evolution of the oceans will be examined scientifically, philosophically and historically. We will integrate spatial and temporal aspects of marine environments.

This is the second in a series of majoręs biology classes covering the principles of biology. The course is an integrated study of basic concepts concerning animal biology emphasizing animal evolution, diversity, phylogeny and a comparative look at general principles of animal form and function. This course is a lab science class and students will be required to participate in weekly lab activities and document their lab work for successful course completion.

Biol & 213 is the third course of a year-long series of biology courses for Biology majors. The first third of the course surveys prokaryotes, protists, fungi, and plants, focusing on diversity, evolution, and life cycles from an evolutionary perspective. We will then describe plant anatomy, physiology, growth, responses to the environment, and reproduction, emphasizing flowering plants. We will finish with ecology, focusing on population, and community ecology and expanding outward to ecosystems and the introduction of biodiversity and conservation.

Welcome to Microbiology, an OpenStax resource. This textbook was written to increase student access to high-quality learning materials, maintaining highest standards of academic rigor at little to no cost.

Microbiology is designed to cover the scope and sequence requirements for the single-semester Microbiology course for non-majors. The book presents the core concepts of microbiology with a focus on applications for careers in allied health. The pedagogical features of Microbiology make the material interesting and accessible to students while maintaining the career-application focus and scientific rigor inherent in the subject matter.

A brief Table of Contents follows. While we have made every effort to align the Table of Contents with the needs of our audience, we recognize that some instructors may prefer to teach topics in a different order. A particular strength of Microbiology is that instructors can customize the book, adapting it to the approach that works best in their classroom.

Chapter 1: An Invisible World
Chapter 2: How We See the Invisible World
Chapter 3: The Cell
Chapter 4: Prokaryotic Diversity
Chapter 5: The Eukaryotes of Microbiology
Chapter 6: Acellular Pathogens
Chapter 7: Microbial Biochemistry
Chapter 8: Microbial Metabolism
Chapter 9: Microbial Growth
Chapter 10: Biochemistry of the Genome
Chapter 11: Mechanisms of Microbial Genetics
Chapter 12: Modern Applications of Microbial Genetics
Chapter 13: Control of Microbial Growth
Chapter 14: Antimicrobial Drugs
Chapter 15: Microbial Mechanisms of Pathogenicity
Chapter 16: Disease and Epidemiology
Chapter 17: Innate Nonspecific Host Defenses
Chapter 18: Adaptive Specific Host Defenses
Chapter 19: Diseases of the Immune System
Chapter 20: Laboratory Analysis of the Immune Response
Chapter 21: Skin and Eye Infections
Chapter 22: Respiratory System Infections
Chapter 23: Urogenital System Infections
Chapter 24: Digestive System Infections
Chapter 25: Circulatory and Lymphatic System Infections
Chapter 26: Nervous System Infections
Appendix A: Fundamentals of Physics and Chemistry Important to Microbiology
Appendix B: Mathematical Basics
Appendix C: Metabolic Pathways
Appendix D: Taxonomy of Clinically Relevant Microorganisms
Appendix E: Glossary

Detailed analysis of the biochemical mechanisms that control the maintenance, expression, and evolution of prokaryotic and eukaryotic genomes. Topics covered in lecture and readings of relevant literature include: gene regulation, DNA replication, genetic recombination, and translation. Logic of experimental design and data analysis emphasized. Presentations include both lectures and group discussions of representative papers from the literature.

With the Genetics Tool, you can: * Cross two organisms * Self-cross one organism * Create mutant versions of one organismWith the Biochemistry Tool, you can: * Look at the structures and colors of the pigment proteins found in one organism * Design proteins and observe their shapes and colors * Compare the amino acid sequences of different pigment proteinsWith the Molecular Biology Tool, you can: * Look at the DNA, mRNA and protein sequences of pigment protein genes * Design genes and observe the colors of the resulting proteins by editing the top DNA strand * Compare the DNA sequences of different pigment protein genes * Create new organisms by specifying their DNA sequences

This course is an introduction to problems about creativity as it pervades human experience and behavior. Questions about imagination and innovation are studied in relation to the history of philosophy as well as more recent work in philosophy, affective psychology, cognitive studies, and art theory. Readings and guidance are aligned with the student's focus of interest.

Biology is designed for multi-semester biology courses for science majors. It is grounded on an evolutionary basis and includes exciting features that highlight careers in the biological sciences and everyday applications of the concepts at hand. To meet the needs of today’s instructors and students, some content has been strategically condensed while maintaining the overall scope and coverage of traditional texts for this course. Instructors can customize the book, adapting it to the approach that works best in their classroom. Biology also includes an innovative art program that incorporates critical thinking and clicker questions to help students understand—and apply—key concepts.