In this activity, students will review and practice naming their body parts in Spanish. They will also use the vocabulary they already know to give clues to their classmates to describe a body part. Students will practice asking and answering questions relating to the body and come up with solutions for illnesses.

This resource provides an overview of the Personal and Professional Development activities and requirements embedded within the eighteen month pre-clinical part of the Graduate Entry Medicine course and the portfolio that students are required to maintain for the duration of the course.

The Graduate Entry Medicine (GEM) course comprises two key themes:

1. Basic and Clinical Sciences (BCS)

Modules 7 to 9 (GEM year 2)
Modules 1 to 6 (GEM year 1)

2. Personal and Professional Development (PPD)

Module 2 (GEM year 2)
Module 1 (GEM year 1)

The Personal and Professional Development modules of the GEM course centre around the concept of professionalism. They integrate basic communication and physical examination skills and encourage you to develop professional behaviour and attitudes and an awareness of how ethical principles underpin clinical practice. These are core skills for doctors and their importance is emphasised by the General Medical Council in the publication “Good Medical Practice”.

Areas covered under the umbrella of PPD include:

• Early Clinical Experience (ECE)
(General Practice visits) – led by the Director of Clinical Skills

• Professional Competencies
(practical clinical and technical skills) – led by the Director of Clinical Skills

• Professional Values
(attitudes and behaviour) – led by the Head of PPD

Module Codes: A12P1G & A12P2G

Year: 2010 to 2012

Suitable for study at: Level 2

Credits: 15

Target Students: Restricted to students registered for the GEM (Graduate Entry Medicine) programme There is a limited number of places on this module. Students are reminded that enrolments which are not agreed by the Offering School in advance may be cancelled without notice.

Prerequisites: Restricted to students registered for the GEM (Graduate Entry Medicine) programme

Corequisites: None

Offering School: Graduate Entry Medicine and Health

In a class demonstration, the teacher places different pill types ("chalk" pill, gel pill, and gel tablet) into separate glass beakers of vinegar, representing human stomach acid. After 20-30 minutes, the pills dissolve. Students observe which dissolve the fastest, and discuss the remnants of the various pills. What they learn contributes to their ongoing objective to answer the challenge question presented in lesson 1 of this unit.

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:

"Many eukaryotic cells make and release small pockets of membrane called extracellular vesicles (EVs). EVs facilitate communication between cells in an organism and can transport many molecules like proteins, RNA, and lipids. Plants are no exception, and many types of EVs can be isolated from their juice, flesh, and roots. In the plants themselves, these EVs facilitate a range of critical functions like immunity, development, and plant–fungi communication. But EVs derived from plants could even have a place in human medicine. In particular, these EVS could be used to transport medications. Plant-derived EVs are more biodegradable and typically less expensive to generate than conventional synthetic carriers, as they can be extracted in bulk. This field is in its early stages, but studies have suggested that plant-derived EVs may also be less toxic and allergenic than conventional carriers..."

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

An interactive lesson template for Medical Office Assistants (MOA). It covers the:
* legal duties of a MOA with regard to prescriptions and drug storage
* parts of a prescription
* common abbreviations
* drug types, actions, delivery methods, and administration
Prescription Drugs for the MOA contains links to free downloadable files for practice, and a quiz.

This course provides a comprehensive overview of human pathology with emphasis on mechanisms of disease and diagnostic medicine. Topics include:

Cellular Mechanisms of Disease
Molecular Pathology
Pathology of Major Organ Systems
Review of Diagnostic Tools from Traditional Surgical Pathology to Diagnostic Spectroscopy
Functional and Molecular Imaging
Molecular Diagnostics

In addition to lectures, one of the two weekly sessions includes a 2-3 hour laboratory component. Periodically, time will also be devoted to minicases.
Lecturers
Prof. Jon Aster, Prof. Frederick Bieber, Prof. Carlo Brugnara, Prof. Robert B. Colvin, Prof. Christopher Crum , Prof. Douglas Dockery, Prof. Mel Feany, Prof. Michael Feld, Prof. Jonathan Fletcher, Prof. Michael Gimbrone, Prof. Todd Golub, Prof. Frank B. Hu, Prof. Donald Ingber, Prof. Hart Lidov, Prof. David Louis, Prof. Richard Mitchell, Prof. Fiona Murray, Prof. Mark Redston, Prof. Helmut Rennke, Prof. Bruce Rosen, Prof. Frederick Schoen, Prof. Christine Seidman

In this video segment adapted from A Science Odyssey, follow two scientists and their Nobel Prize-winning efforts to cure bacterial infections using penicillin.

Students reinforce their knowledge of the different parts of the digestive system and explore the concept of simulation by developing a pill coating that can withstand the churning actions and acidic environment found in the stomach. Teams test the coating durability by using a clear soda to simulate stomach acid.

Students experience the steps of the engineering design process as they design solutions for a real-world problem that could affect their health. After a quick review of the treatment processes that municipal water goes through before it comes from the tap, they learn about the still-present measurable contamination of drinking water due to anthropogenic (human-made) chemicals. Substances such as prescription medication, pesticides and hormones are detected in the drinking water supplies of American and European metropolitan cities. Using chlorine as a proxy for estrogen and other drugs found in water, student groups design and test prototype devices that remove the contamination as efficiently and effectively as possible. They use plastic tubing and assorted materials such as activated carbon, cotton balls, felt and cloth to create filters with the capability to regulate water flow to optimize the cleaning effect. They use water quality test strips to assess their success and redesign for improvement. They conclude by writing comprehensive summary design reports.

A framework of public hygiene and epidemiology is given. Human pathology related to water and sanitation is dealt with, as well as the relation between health and society and environment. The student will get insight in the consequences of his/her interventions to the public health. The civil engineer who works in the health field has to be able to communicate adequately with health authorities and medical doctors, in The Netherlands as well as abroad.

Pulmonary Pathophysiology for Pre-Clinical Students is an undergraduate medical-level resource for foundational knowledge of pulmonary pathophysiology. This text is designed for a pre-clinical undergraduate medical curriculum and is aligned to USMLE(r) (United States Medical Licensing Examination) content guidelines. The text is meant to provide the essential information in a concise format that would allow learner preparation to engage in an active classroom. Clinical correlates and additional application of content is intended to be provided in the classroom experience. The text assumes that the students will have an understanding of basic pulmonary physiology that will be helpful to understand the content presented here. This resource should be assistive to the learner later in medical school and for exam preparation given the material is presented in a succinct manner, with a focus on high-yield concepts.

The 82-page text was created specifically for use by pre-clinical students at Virginia Tech Carilion School of Medicine and was based on faculty experience and peer review to guide development and hone important topics.

Available Formats
ISBN 978-1-957213-08-8 (PDF)
ISBN 978-1-957213-11-8 (ePub)
ISBN 978-1-957213-09-5 (print) https://www.amazon.com/Pulmonary-Pathophysiology-Pre-Clinical-Students-Andrew/dp/1957213094
ISBN 978-1-957213-10-1 (Pressbooks)
https://pressbooks.lib.vt.edu/pulmonarypathophysiology
Also available via LibreTexts: https://med.libretexts.org/@go/page/34444

How to Adopt this Book
Instructors reviewing, adopting, or adapting parts or the whole of the text are requested to register their interest at: https://bit.ly/interest-preclinical.

Instructors and subject matter experts interested in and sharing their original course materials relevant to pre-clinical education are requested to join the instructor portal at https://www.oercommons.org/groups/pre-clinical-resources/10133.

Features of this Book
1. Detailed learning objectives are provided at the beginning of each chapter;
2. High resolution, color contrasting figures illustrate concepts, relationships, and processes throughout;
3. Subsection summary tables
4. End of chapter lists provide additional sources of information; and
5. Accessibility features including structured heads and alternative-text provide access for readers accessing the work via a screen-reader.

Table of Contents
1: The Obstructive Lung Diseases
2: Upper Airway Infections
3: Lower Airway Infections
4: The Restrictive Lung Diseases
5: Acute Respiratory Distress Syndrome
6: Lung Cancer
7: Pulmonary Embolism
8: Immunological Diseases of the Lung
9: Pleural Disease

Suggested Citation
Binks, Andrew., (2022). Pulmonary Pathophysiology for Pre-Clinical Students, Roanoke: Virginia Tech Carilion School of Medicine. https://doi.org/10.21061/pulmonarypathophysiology. Licensed with CC BY NC-SA 4.0.

Other Titles in This Series
LeClair, R., (2021) Cell Biology, Genetics, and Biochemistry for Pre-Clinical Students
LeClair, R., (2022) Neuroscience for Pre-Clinical Students
Binks, A., (2022) Cardiovascular Pathophysiology for Pre-Clinical Students
Binks, A. (2022) Pulmonary Physiology for Pre-Clinical Students 
Sign up here to receive alerts regarding new titles.

About the Author
Dr. Andrew Binks is a cardiopulmonary physiologist who gained his BSc (Hons) in Physiological Sciences at the University of Newcastle upon Tyne, then a MSc in Human and Applied Physiology from King’s College, London. He returned to Newcastle to do his PhD and study the underlying physiological mechanisms of dyspnea, the cardinal symptom of cardiopulmonary disease. He continued investigating dyspnea at Harvard School of Public Health as a postdoctoral fellow and then as a research scientist. After seven years at Harvard, Andrew took his first faculty position at the University of New England where he taught cardiovascular and pulmonary physiology to health profession and medical students. He continued to teach medical students their heart and lung physiology after moving to the University of South Carolina’s Medical School in Greenville where he also directed the school’s heart and lung pathophysiology courses. Andrew currently teaches heart and lung physiology and pathophysiology at Virginia Tech Carilion School of Medicine, directs the heart and lung pathophysiology course and has also served as the departmental director of faculty development.

In his two decades of teaching medical physiology, Andrew has regularly drawn upon his dyspnea research experience to generate an active, clinically focused approach to medical education. This book is part of that approach and supports students preparing for class with the basic information with the intention to apply and contextualize that information in a guided case-based classroom experience.

Andrew has published numerous peer-reviewed research papers and book chapters about dyspnea and about contemporary medical education. He has also given keynote presentations, faculty workshops and international webinars to promote effective medical education for the modern adult learner.

Accessibility Note
The University Libraries at Virginia Tech and Virginia Tech Publishing are committed to making its publications accessible in accordance with the Americans with Disabilities Act of 1990. The HTML (Pressbooks) and ePub versions of this book utilize header structures and include alternative text which allow for machine-readability.

Please report any errors at https://bit.ly/feedback-preclinical

Pulmonary Physiology for Pre-Clinical Students is an undergraduate medical-level resource for foundational knowledge of pulmonary physiology. This text is designed for a pre-clinical medical curriculum and is aligned to USMLE(r) (United States Medical Licensing Examination) content guidelines. The text is meant to provide the essential information in a concise format that would allow learner preparation to engage in an active classroom. Clinical correlates and additional application of content is intended to be provided in the classroom experience. This resource should be assistive to the learner later in medical school and for exam preparation given the material is presented in a succinct manner, with a focus on high-yield concepts.

The 101-page text was created specifically for use by pre-clinical students at Virginia Tech Carilion School of Medicine and was based on faculty experience and peer review to guide development and hone important topics.

Available Formats
ISBN 978-1-957213-12-5 (PDF)
ISBN 978-1-957213-14-9 (ePub)
ISBN 978-1-957213-13-2 (print) https://www.amazon.com/Pulmonary-Physiology-Pre-Clinical-Students-Andrew/dp/1957213132
ISBN 978-1-957213-15-6 (Pressbooks)
https://pressbooks.lib.vt.edu/pulmonaryphysiology
Also available via LibreTexts: https://med.libretexts.org/@go/page/34378

How to Adopt this Book
Instructors reviewing, adopting, or adapting parts or the whole of the text are requested to register their interest at: https://bit.ly/interest-preclinical.

Instructors and subject matter experts interested in and sharing their original course materials relevant to pre-clinical education are requested to join the instructor portal at https://www.oercommons.org/groups/pre-clinical-resources/10133.

Features of this Book
1. Detailed learning objectives are provided at the beginning of each chapter;
2. High resolution, color contrasting figures illustrate concepts, relationships, and processes throughout;
3. Subsection summary tables
4. End of chapter lists provide additional sources of information; and
5. Accessibility features including structured heads and alternative-text provide access for readers accessing the work via a screen-reader.

Table of Contents
1: Fundamentals
2: Mechanics of the Lungs
3: Lung Volumes and Compliance
4: Distribution of Ventilation
5: Airflow and Airway Resistance
6: Dynamic Airway Compression
7: Fundamentals of Gas Exchange
8: Perfusion and Diffusion Limitations in Gas Exchange
9: Pulmonary Blood Flow
10: Pulmonary Capillaries and Non-Ventilatory Function
11: Arterial CO₂ and Ph
12: Alkalosis and Acidosis
13: Ventilation and Perfusion
14: The Alveolar Gas Equation and Alveolar-Arterial PO₂ Difference
15: Pulmonary Shunts
16: Gas Transport
17: Control of Breathing
18: Dyspnea

Suggested Citation
Binks, Andrew., (2022). Pulmonary Physiology for Pre-Clinical Students, Roanoke: Virginia Tech Carilion School of Medicine. https://doi.org/10.21061/pulmonaryphysiology. Licensed with CC BY NC-SA 4.0.

Other Titles in This Series
LeClair, R., (2021) Cell Biology, Genetics, and Biochemistry for Pre-Clinical Students
LeClair, R., (2022) Neuroscience for Pre-Clinical Students
Binks, A., (2022) Cardiovascular Pathophysiology for Pre-Clinical Students
Binks, A. (2022) Pulmonary Pathophysiology for Pre-Clinical Students 
Sign up here to receive alerts regarding new titles.

About the Author
Dr. Andrew Binks is a cardiopulmonary physiologist who gained his BSc (Hons) in Physiological Sciences at the University of Newcastle upon Tyne, then a MSc in Human and Applied Physiology from King’s College, London. He returned to Newcastle to do his PhD and study the underlying physiological mechanisms of dyspnea, the cardinal symptom of cardiopulmonary disease. He continued investigating dyspnea at Harvard School of Public Health as a postdoctoral fellow and then as a research scientist. After seven years at Harvard, Andrew took his first faculty position at the University of New England where he taught cardiovascular and pulmonary physiology to health profession and medical students. He continued to teach medical students their heart and lung physiology after moving to the University of South Carolina’s Medical School in Greenville where he also directed the school’s heart and lung pathophysiology courses. Andrew currently teaches heart and lung physiology and pathophysiology at Virginia Tech Carilion School of Medicine, directs the heart and lung pathophysiology course and has also served as the departmental director of faculty development.

In his two decades of teaching medical physiology, Andrew has regularly drawn upon his dyspnea research experience to generate an active, clinically focused approach to medical education. This book is part of that approach and supports students preparing for class with the basic information with the intention to apply and contextualize that information in a guided case-based classroom experience.

Andrew has published numerous peer-reviewed research papers and book chapters about dyspnea and about contemporary medical education. He has also given keynote presentations, faculty workshops and international webinars to promote effective medical education for the modern adult learner.

Accessibility Note
The University Libraries at Virginia Tech and Virginia Tech Publishing are committed to making its publications accessible in accordance with the Americans with Disabilities Act of 1990. The HTML (Pressbooks) and ePub versions of this book utilize header structures and include alternative text which allow for machine-readability.

Please report any errors at https://bit.ly/feedback-preclinical

In this video segment adapted from NOVA scienceNOW, learn about RNAi's potential to treat a wide range of genetic and infectious diseases.

Radiation Oncology is a rapidly changing field with new advances being made daily. As a consequence, any textbook becomes out-of-date almost immediately after it is published. Thus, the WikiBook format is ideal for a textbook of radiation oncology, as updates can be made constantly as new information becomes available.

In this activity, students will review and practice naming their body parts in Spanish. They will also use the vocabulary they already know to give clues to their classmates to describe a body part.

In this activity, students will review and practice naming their body parts in Spanish. They will also use the vocabulary they already know to give clues to their classmates to describe a body part. Students will practice asking and answering questions relating to the body and come up with solutions for illnesses.

In this activity, students will learn what medicines treat which conditions and which relieve symptoms of illness in the target language. Students will learn to describe medicines and symptoms to be relieved. Students will discuss home remedies in Mexico. Students will also compare and contrast medicines and home remedies in the United States in comparison to Mexico.

Students will be able to recount events that have happened to them using vocabulary about health and body parts. Students will learn to discuss injuries, illness, and medical related events. Students will also learn more about insurance and medical costs.

Students will be able to recount events that have happened to them using vocabulary about health and body parts.