This edition includes a number of new study aids which are the product of a Student Advisory Group (see Authors page) conceived and lead by Laura Bricklin, then a second-year medical student. They include a boxed narrative OVERVIEW opening each disease-oriented chapter or major section, highlighted MARGINAL NOTES judged to be “high yield” for Step 1 preparation, and bulleted lists of KEY CONCLUSIONS at the end of major sections. A THINK ➔ APPLY feature randomly inserts thought-provoking questions into the body of the text, which are answered at the bottom of the page. These new features are explained in detail and illustrated on pages iv and v.
The back of the book includes two more review tools. Infectious Diseases: Syndromes and Etiologies is a set of tables that brings together the infectious agents (viruses, bacteria, fungi, parasites) discussed separately in Parts II through V as probable causes of the major infection syndromes (pneumonia, arthritis, diarrhea, etc.). It is hoped these will be of value when the student prepares for case discussion exercises or sees patients. The 100 Practice Questions are in USMLE format and in addition to the ones at the end of earlier chapters.
For any textbook, dealing with the onslaught of new information is a major challenge. In this edition, much new material has been included, but to keep the student from being overwhelmed, older or less important information has been deleted to keep the size of this book no larger than of the sixth edition. As a rule of thumb, material on classic microbial structures, toxins, and the like in the Organism section has been trimmed unless its role is clearly explained in the Disease section. At the same time, we have tried not to eliminate detail to the point of becoming synoptic and uninteresting. Genetics is one of the greatest challenges in this regard. Without doubt this is where major progress is being made in understanding infectious diseases, but a coherent discussion may require using the names and abbreviations of genes, their products, and multiple regulators to tell a complete story. Whenever possible we have tried to tell the story without all the code language. We have also tried to fully describe the major genetic mechanisms in general chapters and then refer to them again when that mechanism is deployed by a pathogen. For example, Neisseria gonorrhoeae is used to explain the genetic mechanisms for antigenic variation in a general chapter on bacterial pathogenesis (Chapter 22), but how it influences its disease, gonorrhea, is taken up with its genus Neisseria (Chapter 30).
A saving grace is that our topic is important, dynamic, and fascinating—not just to us but to the public at large. Newspaper headlines now carry not only the new names of emerging threats like Zika virus but also the antigenic formulas of more familiar pathogens like E coli and influenza virus. Resistance to antimicrobial agents and the havoc created by antivaccine movements are regular topics on the evening news. I1t is not all bad news. We sense a new optimism that deeper scientific understanding of worldwide scourges like HIV/AIDS, tuberculosis, and malaria will lead to their control. We are hopeful that the basis for understanding these changes is clearly laid out in the pages of this book.