Chapter 1. Fundamentals of Scientific Inquiry in the Biological Sciences I

1.1

BIO 204 | Fall 2015

9th Edition
Undergraduate Biology
Stony Brook University


Michael J. Cressy, Ph.D.
Joan M. Miyazaki
Marvin H. O'Neal III, Ph.D.
Deborah A. Spikes

1.2 Copyright

Copyright © 2016 by Michael J. Cressy, Ph.D., Joan M. Miyazaki, Marvin H. O’Neal III, Ph.D., Deborah A. Spikes, and Undergraduate Biology, Stony Brook University

Copyright © 2016 by Hayden-McNeil, LLC on illustrations provided

Photos provided by Hayden-McNeil, LLC are owned or used under license

All rights reserved.

Permission in writing must be obtained from the publisher before any part of this work may be reproduced or transmitted in any form or by any means, electronic or mechanical, including photocopying and recording, or by any information storage or retrieval system.

Printed in the United States of America

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ISBN 978-0-7380-7848-9

Hayden-McNeil Publishing
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Acknowledgements

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This is our ninth year teaching Fundamentals of Scientific Inquiry in the Biological Sciences. BIO 204 and BIO 205/207 are sequential laboratories that focus on critical thinking and problem solving instead of memorization and the completion of cookbook activities. We have designed a two-semester curriculum that prepares you for scientific inquiry, experimental design, and use of modern instrumentation.

This new vision of laboratory science education was possible largely because of the dedication and hard work of Kelly O’Donnell, Roberta Harnett, and David Ruggerio in the Fall of 2007. We particularly wish to thank the curriculum committee members: Eugene Katz, John True, Neta Dean, Kate Dilger, and Daniel Apple for their valuable insight into the structure and design of these laboratories. This edition includes labs developed by M. Caitlin Fisher-Reid, Kelly L. O’Donnell, Center for Biomolecular Modeling at the Milwaukee School of Engineering, as well as a modified lab from BioRad Laboratories. They are not responsible for manuscript errors; we assume all responsibility of text and information accuracy.

This manual is not entirely an original text. Rather, it is the compilation of many years of dedicated service from exceptionally talented students, faculty, and staff. We are honored to have worked with them. Leo Shapiro, Paul Wilson, and R. Geeta made contributions to the invertebrates, systematics, and evolution lab exercises. The greenhouse lab would not be possible without Mike Axelrod and John Klump’s rock-solid competence and good humor. This course would not function without the vast talents and efforts of the professional, administrative, and advising staff of Undergraduate Biology.

The teaching philosophy used in this manual was strongly influenced by Bill Dawes, Diane Ebert-May, Jackie Gennon-Brooks, Daniel Apple, Marjorie Kandel, and Barbara Panessa-Warren—over the years they have given us a great deal of creative and helpful advice. The Howard Hughes Medical Institute and the National Academies of Sciences Summer Institute on Undergraduate Education trained us and supported and encouraged our work to transform undergraduate science education to meet the needs of our students, the future scientists and professionals of the 21st century.

M. J. Cressy, J. M. Miyazaki, D. A. Spikes, and M. H. O’Neal III Stony Brook University

Stony Brook University

1.3 General Information

Course Objectives:

This course is designed to be an introduction to your career in the biological sciences and prepare you for upper division biology courses. The most critical aspect of this preparation is to develop scientific thought. In addition, you will be introduced to common laboratory practices and procedures, learn to conduct basic experiments, and practice experimental design using scientific reasoning. This course is divided into 14 labs, each of which falls into these broad categories: Laboratory Skills, Managing Data, Molecular Techniques, Scientific Communication, and Experimental Design. For each lab there are learning goals, and for every activity there are learning objectives. Learning objectives are used to construct the activities, assessments, assignments, and exams. Please use these to guide your preparation, lab work, and studying. Learning objectives are measurable goals that help you determine if you are progressing toward the larger goals of the course. In other words, successful completion of the learning objectives demonstrates that you have a mastery of the knowledge and skills for the course.

College laboratories are training grounds for your future work environment, and it takes more than the mastery of a topic to succeed as a professional. You are expected to become a good observer, listener, oral communicator, reader, and writer in the biological sciences. To excel in this course, you will be required to understand and focus on the objectives of a project, think critically and creatively, categorize concepts, make connections, understand and use new terminology, and efficiently manage your time. You will use computers and statistics to collect and analyze data. At times, you will be called upon to be a leader, at other times to be an independent self-starter, a team player, or a follower. You will also be required to present your work in both oral and written formats.

Upon completion of BIO 204/205, you will have improved these 21st-century skills identified by The National Research Council in a recent report: adaptability, complex communication/social skills, non-routine problem solving, self-management/development, and systems thinking.

1.4 Required Materials

1.5 Use of Animals

Biology is the science of life, and learning biology requires the study of living organisms. In this course, you will be required to handle live plants and animals. You will also be expected to dissect preserved animals in some of the laboratory exercises. In every case, you are expected to handle all living organisms properly based on this manual as well as instructions from your instructor. If you have objections to these requirements, you must meet with Dr. O’Neal or submit in writing your objections within the first two weeks of the course.

1.6 Students with Special Needs

If you have any condition, such as a physical, psychological, medical, or learning disability which will make it difficult for you to carry out the work for this course, or which will require extra time on examinations, please contact the staff in the Disabled Student Services Office (DSS), 128 Educational Communications Center (ECC), 632-6748. DSS will review your concerns and determine, with you, what accommodations are necessary and appropriate. Letters of notification should be addressed to Dr. Marvin O’Neal, Z=5110.

1.7 Websites

All lectures, demonstrations, administrative changes, communication, and course updates will be presented using Launchpad, Blackboard, and/or your official SBU email: “firstname.lastname@stonybrook.edu”. A link to Blackboard can be found on our departmental website at http://www.bio.sunysb.edu.

1.8 Help

An entire team in Undergraduate Biology is here to help you. Follow these procedures to get your questions answered quickly and accurately:

  1. Ask your instructor for help. ALL instructors are required to hold one office hour each week per section. Feel free to speak with any instructor teaching this course. They are required to help all students taking BIO 204. Office hours are open to any student taking BIO 204.
  2. Email faculty for help at our course email: introbiolabs@stonybrook.edu Your email will be answered by one of the following faculty members:

3. Contact staff for specific help (see below):

1.9 Course Administration Roles

  1. Course Director: Dr. O’Neal is responsible for all course content, policies, and final letter grades.
  2. Faculty: Deborah Spikes and Rebecca Garcia are responsible for the biology lab curriculum, the learning facilities including the Biology Learning Labs, and instructors.
  3. Course Administrators: Lynette Giordano is responsible for add/drop forms, section changes, or absences (see Attendance Policy below). Diane Pauciullo is responsible for the administration of exams including scantron issues and scheduling make-ups. Course administrators are not responsible for the policies implemented. You may see a faculty member or Dr. O’Neal for difficult, personal, or private issues or problems that remain unresolved.
  4. Instructors: This is a large course, but you should not feel shy or embarrassed to ask questions during lab or to come to posted office hours. Instructors hold one office hour per section every week in the Biology Learning Center (Room 114 of CMM/BLL); check the schedule posted on the door and on Blackboard. Faculty office hours are also posted on the course website. Feel free to visit G05 or email introbiolabs@stonybrook.edu to schedule an appointment.

1.10 Blackboard

Each student has two Blackboard sites for BIO 204. Section 204.R## is used for communication between faculty and all students, which includes administrative changes, course updates, and exam grades. The individual lab sections each have their own Blackboard site (L##) and is used for section-specific communication between the instructor and the students in that lab section, including e-portfolio uploads, discussion board posts, quiz grades, group collaboration, and section emails. Check both Blackboard sites weekly.

1.11 Laboratory Rules

  1. Do not bring food or drink into the labs. Students who choose to eat and drink in lab will be asked to leave and will receive a zero for their Lab Performance score.
  2. Computers are to be used for lab activities only. Students are not allowed to download programs, change shortcuts, or alter any settings on the lab computers. Please remember to log off of all lab computers and do not share accounts or passwords with fellow students. Students are welcome to bring their own laptops or tablets to lab if they are used for professional activities. Unless asked to do so by your instructor, do not engage in any social media, video calls, games, or activities unrelated to laboratory.
  3. Full lab participation is expected. Your lab performance grade is based on participation during experiments and data collection, group involvement, inquiry, cooperation, and techniques. Tardiness will adversely affect your grade. Zeroes are given for unexcused absences. Repeated absences (3 or more) will result in failure of the course.
  4. Electronic communication devices, including cellular phones and tablets, should be used during laboratory to take pictures, document experiments, or foster collaboration. Please do not make personal calls or text during laboratory unless it directly applies to the assigned activity.
  5. View online lectures and demonstrations to understand the concepts and techniques before each lab. Students who have performed well in this lab “actively” view the online material by taking clear and organized notes and recording any questions that they have about course material. All questions should be brought to the attention of your instructor prior to lab.
  6. Stay ahead, and if you fall behind, do not wait to catch up. This course covers too much information to learn by cramming. Online lectures are always available to you; there is no excuse for missing lecture information. If you run into personal problems that make it difficult to keep up, see a faculty member as soon as possible to work something out.
  7. Recitations are a required component of this course. You should attend and actively participate. Preparation for recitation includes watching the vodcast and reading the lab manual. Recitations will be Echo360 recorded and placed on Bb.
  8. Monitor your grades and progress. If you are not getting the grades you want, see your instructor immediately, and a faculty member if necessary, to work out a plan to improve your performance. Do not walk into G05 at the end of the semester requesting that your grade be changed because you need a better grade to achieve your career goals. At this point, it will be too late.

1.12 Attendance Policy

Lab attendance is required. You are expected to attend and participate in every lab for the full period. If you miss three normally scheduled labs, for any reason (excused or unexcused), you will automatically fail this course. When in lab, you should be working. Lab performance (professionalism, technical skills, and analytical skills) are a part of your grade. Tardiness is not acceptable and incurs a performance grade penalty.

Excused Absences:An unavoidable absence from lab which is due to sudden illness or a death in the family may be excused. Documentation must be submitted to the Course Administrator, Lynette Giordano (Office: 110 CMM/BLL, 632-8530). Students are only excused from the performance and quiz component for the week of the absence. Excused students are still responsible for all written work, which is due within one week of returning to lab (or the next lab session). Exams and practicals must be taken at regularly scheduled times. Requests to make up an exam should be submitted, in writing, to the Course Director and should be accompanied by an excused absence and written documentation. Permission to make up exams and practicals will be decided on a case-by-case basis.

Make-up Laboratories: There are no regularly scheduled make-up labs. In rare circumstances, you may be permitted to attend another lab section within the regular lab schedule “if” space is available, you bring in a valid excuse, AND are approved by the Course Administrator, Lynette Giordano (Office: 110 CMM/BLL, 632-8530). The permission form will be emailed from the Course Administrator to the instructor of the make-up lab and to the instructor of your SOLAR lab section. Making up a laboratory does not negate an unexcused absence.

Note: If you have an official, pre-scheduled university event such as an athletic competition or an exam conflict in another class, then you should schedule make-up laboratories or exams by the second week of classes. Last-minute requests will not be honored.

Unexcused Absences: Zeroes will be given for all lab work including lab performance and in-class activities if you are absent (unexcused). Work that is missed due to lateness will not be excused. Lab work that is due on the day of an unexcused absence should be submitted electronically by the beginning of lab to be accepted as “on time.”

Calculating Penalties for Late Work: For assignments to be accepted on time, they must be submitted by the beginning of lab on the due date. Late assignments will be penalized 10% of the total point value per day, except for late work due to an excused absence (see above). For example, an assignment worth 100 points that is one day late will receive a grade no higher than 90; two days late, no higher than 80, etc. Assignments are graded based on a rubric and the percent score is multiplied by the late penalty score. If you received 78% based on the rubric and were two days late, your final grade would be 62.4% (0.78 × 80). Assignments received more than seven days after the due date will receive a grade of zero.

1.13 Academic Integrity

Academic honesty and integrity are fundamental to all aspects of academic and scholarly work. Therefore, consistent with University policy, we view any form of academic dishonesty with utmost seriousness and will take the necessary steps to protect the academic integrity of this course.

  1. Definition: “Academic dishonesty includes any act that is designed to obtain fraudulently, either for oneself or for someone else, academic credit, grades, or other recognition that is not properly earned or that adversely affects another’s grade.” The following represents examples of this but does not constitute an exhaustive list:

  • Cheating on exams or assignments by the use of books, electronic devices, notes, or other aids when these are not permitted, including collusion or copying from another student.
  • Submitting the same paper in more than one course or repeatedly within the same course without permission of the instructors.
  • Plagiarizing: copying someone else’s writing or paraphrasing it too closely, even if it constitutes only some of your written assignment.
  • Falsifying documents or records related to credit, grades, status (e.g., adds and drops, GPNC grading), or other academic matters.
  • Altering an exam or paper after it has been graded in order to request a grade change.
  • Stealing, concealing, destroying, or inappropriately modifying classroom or other instructional material, such as posted exams, laboratory supplies, or computer programs.
  • Preventing relevant material from being subjected to academic evaluation.
  1. Action: The strongest action allowed by University guidelines will be followed for each incident. Without exception, all incidents will be submitted to the University Academic Judiciary Committee.
  1. Result: All students found guilty of academic dishonesty are required to take the University’s course on academic integrity (the “Q” course); however, additional penalties may also be levied. These penalties could range from receiving a “0” on an assignment or exam, failure of a course, and possibly suspension or expulsion from the University. Once reported, students are subject to the ruling and findings of the Academic Judiciary Committee. Information about the procedures for hearings and other functions (including appeals) can be found on the website referenced below as well as in the Office of Undergraduate Academic Affairs(www.stonybrook.edu/uaa/).

1.14 Student Grades

Recitation (24%) will be held once a week. Attendance and participation are required. Quizzes worth 100 points will be given during recitation using campus-adopted clickers. These are designed to determine if you understand the concepts presented. Reading the lab manual in Launchpad, watching vodcasts, and participating during recitation is sufficient preparation for these quizzes. No make-up quizzes will be given. Participation worth 100 pts. will be determined based on attendance and participation during recitation activities. A problem set worth 40 points will be given during recitation for Lab 5 as a review to recitations 1–4 and as preparation for the final exam.

Lab Performance (6%) is based on your group work (see Appendix A) during experiments, data collection, group discussion, and scientific inquiry. Full participation is expected. All students begin the semester with a perfect 60-point score and receive reductions for tardiness (–2) or lack of participation (–2; not prepared for lab, not performing a group role, regularly leaving during lab, missing a large percentage of lab, etc.). Each week’s deductions will be posted in your section’s Blackboard site (L##) by your instructor.

Exams (20%) include the Competency and Final. NO ONE WILL BE ADMITTED LATE TO THESE EXAMS. Because of the size of this course, we are forced to adhere strictly to this policy. Even if you have a valid excuse, you will not be allowed to take exams if you come late. If you have a valid, documented excuse, see Lynette Giordano immediately. After the exams, if you wish to protest a question or answer, submit your reasoned argument to introbiolabs@stonybrook.edu on the next business day following the posting of the answer key. The Competency Exam tests practical skills using laboratory instrumentation. All questions are posted prior to the exam. Successfully completing practice sessions during lab and in the Biology Learning Center will prepare students for the exam (50 pts.). The Final Exam (150 pts.) is a multiple choice and/or short answer exam designed to measure your progress in the course based on the learning objectives at the beginning of each lab activity. Exams will test your knowledge of content, skills, and critical thinking in the previous labs. You will be required to both learn and apply concepts from this course as well as the prerequisites including General Chemistry and basic computational mathematics.

Scientific Literature Project (15%) is completed in seven weeks and is designed to teach you how to read primary scientific literature. This project includes five major steps: 1) applying a reading strategy, 2) completing a worksheet, 3) actively watching a scientist’s vodcast, 4) presenting a poster summarizing your assigned article to your peers, and 5) writing a summary essay. You will receive feedback on your worksheet (25 pts.), poster (75 pts.), and essay (50 pts.). Because 24 different articles are assigned to each section, your instructor will not grade all parts of this project; instead, 1–2 instructor(s) teaching BIO 204 will be assigned each article and grade the accuracy of your poster and essay. A list of the 24 articles and instructor “experts” will be posted on Launchpad. It is important that you meet with the expert instructor if you have any questions about your assigned article. SPK (Speak Effectively before an Audience): The poster presentation for this project, coupled with the presentation portion of Lab 9 and the GMO debate, are the three assessments used to satisfy the SPK category of Stony Brook’s General Education Curriculum.

Digital Notebook (15%) is an electronic record of your group’s work during laboratories and will be graded twice during the semester (mid = 50 pts. and end = 100 pts.). Your group will be graded based on a uniform scale across all sections (see below). Not submitting assignments results in “0” points awarded. For a group, you may take pictures of your lab notebook and attach them to the discussion board on Blackboard in your section L##.

Lab Report (20%) is based on methods and results sections from Lab 2 and your own Isopod Experiment to be conducted during Lab 9. These reports should be typed and submitted to Blackboard’s SafeAssign. Instructors will use rubrics for more uniform grading across sections which will be posted on Blackboard. Your reports should be structured based on Chapters 4–6 of the SBU edition of Knisely’s A Student Handbook for Writing in Biology which can be found in all labs, including the Biology Learning Center. These two assignments are designed to teach you how to write lab reports and you will be rewarded for improvement in this skill. Specifically, if your second lab report receives a higher percentage than your first, then your first report will be dropped and the second will count for the full 20% (200 pts.) of your total grade.

The following is a summary of the above mentioned components totalling 1000 points:

Course Schedule

Letter Grades are assigned following a meeting between all of the instructors and faculty at the end of the semester. Letter grades are based on your final point total. The following table will help you determine the MINIMUM letter grade that you will receive based on accumulated points. However, we typically add points to a section based on its performance relative to other sections and to the overall averages in each category for the entire class. Therefore, your letter grade may be higher than this scale (for example, in BIO 204 Fall 2008, a score of 875–1000 received an “A” and the “F” range was 0–499 points). Historically, the average letter grade in this course has been approximately a C+/B–. Course grades are not curved. If every student accumulates greater than 933 points by the end of the semester, then everyone will receive an “A.” It is therefore possible for all students within a section to receive an “A” (24/24), although historically the highest number has been 17/22. If extra credit is given, then the letter grade will still be calculated based on the 1000-point scale and not a percent score, even if the total exceeds 1000 points.

Use the following table to monitor your progress in BIO 204:

     

1.15 Laboratory Notebook

Track the progress of your projects using a notebook with NCR paper. Research notes, descriptions, data collection, ideas, and reflections, are fundamental to science. You will be asked to turn in the copied page of these notes at the end of each lab, so keep them neat and up to date. These can be used for weekly quizzes.

Expected Content: Notebooks are records of work accomplished in lab and serve as future reference for protocols used, details of instrumentation use, and roles and credit for work done by group members.

  • Table of Contents —First two pages
  • Your name, group members, group roles, and date—On each page
  • Numbers—Data measurements, counts, etc., in data tables and graphs
  • Visuals—Sketches, figures
  • Text—Write purpose statements, descriptions, and legends. Insights described, quality of questions, additional hypotheses, and evidence of progress are indicators of critical thinking and depth of understanding.
  • Organization and clarity—Legibility and neatness as needed to retrieve information efficiently
  • Pre-lab content—Vodcast and reading notes with answers to discussion questions. These may not be handed in as typed pages. Lab notebooks can be used during quizzes.
  • Academic Integrity—Copying another student’s lab notebook is not acceptable, unless they are in your group and the data were collected as a group. For example, copying raw data from your lab partner’s notebook is typical practice in research labs and is OK in this course. However, copying answers to discussion questions or notes from vodcasts is NOT acceptable.

Grading Standards for Lab Notebook Evaluations:

  • Excellent—Notes are thorough and informative. Measurements recorded in tables (with units), clear and easy to follow, excellent observations, labeled graphs and clear figures with legends, group contributions (roles) included. Insights into understanding or future investigations demonstrate critical thinking and depth of understanding. Details of essential information included (e.g., locality for field work). Individual contributions to group report: all individuals contributed according to their roles. SII for group and lab activities are clearly recorded. Contributions, strengths, areas for improvement, and insights into team contribution and lab activities.
  • Good—Notes are adequate reference for future use. Notes are similar in most ways to the excellent category above, graphs and figures OK, notes acceptable, details OK, readable, neat enough. Some important information is missing or hard to locate. SIIs are adequate.
  • Needs Improvement—Most important information recorded, but overall notes, graphs, and figures are lacking in detail, clarity, and organization, making it difficult to follow this record of lab activities. SIIs are weak or superficial.
  • Failing—Notes are minimal and uninformative—not usable as a reference for future investigations. Sloppy or wasted space. Important information such as name, date, and team members missing. Sketches have no labels or references. SII weak or missing.

Team Roles: Rotate weekly. While all members are responsible for carrying out lab activities, each role carries specific responsibilities. Refer to Appendix A for complete descriptions for each team role for a group of four students: leader, technician, analyst, and recorder (in groups of three students, the leader is also the analyst).

1.16 Habits of Effective Students

Written by Sherryl Broverman

Success is a matter of choice. While obviously not all are born with equal abilities, educators know that those students who achieve high grades do so mostly because of their learning habits. This includes attending all classes and taking good notes, but it also goes much deeper than this. In fact, there is a culture of learning, and, like all cultures, it can be explored and assimilated by those who value it.

Taking Responsibility

The number one attribute of a successful student is taking personal responsibility for your own education. You must realize that you have more to benefit from than anyone else does by taking control of your undergraduate experience. This means:

  • Obtaining and reading the syllabus
  • Doing the readings prior to class
  • Viewing all lectures
  • Actively listening during lecture
  • Re-reading or rewriting your notes in the evening
  • Preparing for lab
  • Understanding lab objectives
  • Fully participating during lab
  • Following up on all lab assignments

This sounds simple and self-evident, but many students set themselves up for failure by not doing even these basic things. Clearly all these things take time and some sacrifice of social activities. However, every learner must do a personal cost-benefit analysis of how they spend their time and what they hope to achieve from their education. Successful students realize that the payoffs can be enormous. Another aspect of taking personal responsibility is realizing that learning does not occur in a vacuum. This means identifying all the resources available to help you learn and achieve success—and using them! The number one resource around you is people: classmates, teaching assistants, and faculty. Your peers are wonderful, and often under-utilized, assets. One hundred people listening to the same lecture often write down different things. If you compare notes with each other (e.g., identifying major concepts and filling in gaps), then you all will benefit. For those questions not resolved by discussions with peers, seek out an instructor, whether graduate student or faculty. Besides it being their job, the majority of people involved in education LIKE to teach and look forward to assisting others in learning. After reviewing your notes, bring them to office hours with questions. Traditionally, students who interact more with instructors/faculty do better on exams.

There are, of course, other resources available to students besides people. The primary one should be this course’s accompanying texts. If an unknown word or term is used during lecture, look it up in the index or examine the definition in the glossary. A capable student also identifies related resources whether they are library references or websites. A caution about websites: not all information on websites has been through the critical review process which is so essential to good science. There is a great deal of misinformation on the web, so beware!

Goal Setting

Another important feature of a successful student is they know how to set personal goals and how to develop strategies for reaching them. The first step in doing this is to set specific goals rather than vague ones; i.e., instead of saying, “I will study tonight,” say “I will read a chapter in chemistry and do ten math problems tonight.” It is also useful to take a long-term goal (“I want to get into graduate school”) and break it down into concrete short-term goals (“I want to get an A or B in biology, so I will do the reading and homework assignments before each class.”). Goals differ from wishes in that they are attainable by personal action. The best goals define the action needed to accomplish them. Most importantly, goals should be realistic and self-chosen, which means some self-awareness is necessary to create them. Only with an attainable and personally valuable goal will you avoid frustration and disappointment.

By following the guidelines presented here you can begin to develop a culture of learning. By doing so, you won’t just enhance your performance as an undergraduate; the majority of the skills listed above (taking personal responsibility, budgeting time, identifying resources, setting goals, etc.) will assist you in achieving success in all walks of life.

1.17 The Importance of Collaboration in Science

Science has always been a cooperative discipline; each new piece of knowledge must be created from the existing knowledge and will in turn lead to even more breakthroughs. Education, on the other hand, has traditionally been something you do on your own: attending lecture, taking notes, studying for tests, sometimes working with a partner in a lab. The skill of cooperating with a team in an organized way to achieve a common goal is fast becoming commonplace in all areas of life, including business and industry, health care, public service, government, and especially education.

Undergraduate students of biology have been discovering the many benefits of teamwork. Collaborating with others allows each of you to accomplish more work, and a higher quality of work, in a shorter period of time. Teamwork allows the development of interpersonal skills that will benefit you in all aspects of your life. Also, individuals in a team benefit by teaching others new skills, learning to negotiate, exercising leadership, working with diversity, and benefiting from the knowledge and skills of others. Students who have completed a semester of group work often say they learned more and learned faster by discussing what they were learning with teammates. It is for reasons such as these that the activities in this course have been designed to incorporate the teamwork process.

As you will realize from your experiences in this course, an effective teamwork process involves a great deal more than simply putting people together in a group with a task to work on. A very valuable way of approaching problems in a group is to have each member of the group perform a defined role. Appendix A lists roles that can help build a strong team and allow you to complete high quality work in a shorter period of time.