Rapid Review Pathology PDF 4th Edition

Summary

Rapid Review Pathology, Fourth Edition is a high-yield textbook covering pathology, ideal for medical students preparing for USMLE and COMLEX exams. The book includes numerous images and updated management of key diseases, making it a valuable resource. It also integrates information from basic and clinical sciences with detailed tables.

Full Transcript

ii Rapid Review Pathology

Study smart with Student Consult
Searchable full text online

Register and activate this title today
at studentconsult.com
Access the full text online
Activation Code
Download images
Add your own notes and bookmarks
Search across all the Student Consult
resources you own online in one place

ALREADY REGISTERED? FIRST-TIME USER?

1. Go to studentconsult.com; Sign in 1. REGISTER
2. Click the “Activate Another Book” Go to studentconsult.com; click “Register Now”
button Fill in your user information and click “Activate your
3. Gently scratch off the surface of account”
the sticker with the edge of a coin 2. ACTIVATE YOUR BOOK
to reveal your Pin code Click the “Activate Another Book” button
4. Enter it into the “Pin code” box; Gently scratch off the surface of the sticker with the
select the title you’ve activated edge of a coin to reveal your Pin code
from the drop-down menu Enter it into the “Pin code” box; select the title
5. Click the “Activate Book” button you’ve activated from the drop-down menu
Click the “Activate Book” button

Access to, and online use of, content through the Student Consult website is for individual use only; library and institutional access and
use are strictly prohibited. For information on products and services available for institutional access, please contact our Account
Support Center at (+1) 877-857-1047. Important note: Purchase of this product includes access to the online version of this edition for
use exclusively by the individual purchaser from the launch of the site. This license and access to the online version operates strictly on
the basis of a single user per PIN number. The sharing of passwords is strictly prohibited, and any attempt to do so will invalidate the
password. Access may not be shared, resold, or otherwise circulated, and will terminate 12 months after publication of the next edition
of this product. Full details and terms of use are available upon registration, and access will be subject to your acceptance of these
terms of use.

For technical assistance: email [email protected]
call 800-401-9962 (inside the US) / call +1-314-995-3200 (outside the US)

ii
 Rapid Review Series

Series Editor
Edward F. Goljan, MD

BEHAVIORAL SCIENCE, SECOND EDITION
Vivian M. Stevens, PhD; Susan K. Redwood, PhD; Jackie L. Neel, DO;
Richard H. Bost, PhD; Nancy W. Van Winkle, PhD; Michael H. Pollak, PhD
BIOCHEMISTRY, THIRD EDITION
John W. Pelley, PhD; Edward F. Goljan, MD

GROSS AND DEVELOPMENTAL ANATOMY, THIRD EDITION
N. Anthony Moore, PhD; William A. Roy, PhD, PT

HISTOLOGY AND CELL BIOLOGY, SECOND EDITION
E. Robert Burns, PhD; M. Donald Cave, PhD

MICROBIOLOGY AND IMMUNOLOGY, THIRD EDITION
Ken S. Rosenthal, PhD; Michael J. Tan, MD

NEUROSCIENCE
James A. Weyhenmeyer, PhD; Eve A. Gallman, PhD

PATHOLOGY, FOURTH EDITION
Edward F. Goljan, MD

PHARMACOLOGY, THIRD EDITION
Thomas L. Pazdernik, PhD; Laszlo Kerecsen, MD

PHYSIOLOGY, SECOND EDITION
Thomas A. Brown, MD

USMLE STEP 2
Michael W. Lawlor, MD, PhD

USMLE STEP 3
David Rolston, MD; Craig Nielsen, MD
RAPID REVIEW
PATHOLOGY FOURTH EDITION

EDWARD F. GOLJAN, MD
Professor
Department of Pathology
Oklahoma State University Center for Health Sciences
College of Osteopathic Medicine
Tulsa, Oklahoma
1600 John F. Kennedy Blvd.
Ste 1800
Philadelphia, PA 19103-2899

RAPID REVIEW PATHOLOGY, FOURTH EDITION 978-0-323-08787-2

Copyright © 2014 by Saunders, an imprint of Elsevier Inc.
Copyright © 2011, 2007, 2004 by Mosby, Inc., an affiliate of Elsevier Inc.

No part of this publication may be reproduced or transmitted in any form or by any means, electronic or
mechanical, including photocopying, recording, or any information storage and retrieval system, without
permission in writing from the publisher. Details on how to seek permission, further information about the
Publisher’s permissions policies and our arrangements with organizations such as the Copyright Clearance
Center and the Copyright Licensing Agency, can be found at our website: www.elsevier.com/permissions.

This book and the individual contributions contained in it are protected under copyright by the Publisher
(other than as may be noted herein).

Notices

Knowledge and best practice in this field are constantly changing. As new research and experience broaden
our understanding, changes in research methods, professional practices, or medical treatment may become
necessary.
Practitioners and researchers must always rely on their own experience and knowledge in evaluating
and using any information, methods, compounds, or experiments described herein. In using such
information or methods they should be mindful of their own safety and the safety of others, including
parties for whom they have a professional responsibility.
With respect to any drug or pharmaceutical products identified, readers are advised to check the most
current information provided (i) on procedures featured or (ii) by the manufacturer of each product to be
administered, to verify the recommended dose or formula, the method and duration of administration,
and contraindications. It is the responsibility of practitioners, relying on their own experience and
knowledge of their patients, to make diagnoses, to determine dosages and the best treatment for each
individual patient, and to take all appropriate safety precautions.
To the fullest extent of the law, neither the Publisher nor the authors, contributors, or editors, assume
any liability for any injury and/or damage to persons or property as a matter of products liability,
negligence or otherwise, or from any use or operation of any methods, products, instructions, or ideas
contained in the material herein.

Library of Congress Cataloging-in-Publication Data

Goljan, Edward F.
Rapid review pathology / Edward F. Goljan.—Ed. 4.
   p. ; cm.—(Rapid review series)
Pathology
Includes bibliographical references and index.
ISBN 978-0-323-08787-2 (pbk. : alk. paper)
I. Title. II. Title: Pathology. III. Series: Rapid review series.
[DNLM: 1. Pathology—Examination Questions. 2. Pathology—Outlines. QZ 18.2]
616.07—dc23
2012042909

Senior Content Strategist: James Merritt
Content Developmental Specialist: Christine Abshire
Publishing Services Manager: Jeff Patterson
Senior Project Manager: Tracey Schriefer
Design Direction: Steven Stave
Working together to grow
libraries in developing countries
Printed in the United States of America. www.elsevier.com | www.bookaid.org | www.sabre.org

Last digit is the print number: 9 8 7 6 5 4 3 2 1
To all our grandchildren—Austin, Bailey, Colby, Dylan, Gabriel, Phin, Rigney, Sofia, and
those great-grandchildren yet to come—thank you for keeping us “young at heart.”
—Nannie and Poppie
 Preface

Writing a new edition of a book always provides an opportunity to improve upon previous
editions. This fourth edition of Rapid Review Pathology reflects these improvements thanks
to many discussions I have had over the past 4 years with my colleagues in the basic
sciences and my students, and comments from students in other medical schools. The
most substantial changes in this new edition include a new chapter entitled “Diagnostic
Testing,” more images, updated management of key diseases, more integration with the
basic and clinical sciences, and more tables to summarize information, particularly in
microbiology.
To users of the last edition of the book (Rapid Review Pathology Revised Reprint, Third
Edition), a list of corrections and additions is available on your Student Consult page in
the electronic version of Rapid Review Pathology, under the Extras tab. For instructions on
how to activate your Student Consult version, see the PIN page on the inside front cover
of your book and go to www.studentconsult.com to activate your PIN.

Edward F. Goljan, MD

vi
 Acknowledgments

The fourth edition of Rapid Review Pathology has been extensively revised to provide
students with even more high-yield information and photographs than in previous
editions. Many of the photographs are grouped together in collages to provide students
with an opportunity to quickly review infectious diseases, dermatology, hematology,
endocrinology, and many other key areas. In addition, the emphasis on margin notes
and increased content in the summary tables provides the student with a “rapid review”
of high-yield material for pathology examinations and USMLE and COMLEX Step
1 and 2 examinations.
As in previous editions, I especially want to thank Ivan Damjanov, MD, PhD, whose
many excellent photographs have been utilized throughout the book. I highly recommend
his recently published Elsevier book, Pathophysiology, as a companion text to the Rapid
Review Pathology text for providing students with an even greater understanding of patho-
physiologic processes in disease. I also thank Edward Klatt, MD, who graciously allowed
the use of so many of his excellent images from Robbins and Cotran Atlas of Pathology, a
resource that I also highly recommend as a source of high-quality images and supplemen-
tary learning.
Special thanks to Nicole DiCicco and Christine Abshire from Elsevier, who kept track
of all the major changes in the third edition and helped facilitate the early publication of
the book. Special thanks also to Karlis Sloka, DO, valued friend and teacher, whose under-
standing of disease processes helped me throughout the entire writing of the new edition.
I want to thank Jim Merritt, Senior Content Strategist of Medical Education, who is the
inspiration and primary energy behind the entire Rapid Review Series. Thanks Jim for a
job well done! Finally, I would like to thank the myriad of medical students who have sent
me e-mails with encouraging words on how the book has helped them not only perform
well on boards, but also become better doctors. In particular, I would like to thank Gabriel
Tonkin, who sent me referenced and updated material on numerous subjects that I used
throughout the writing of the fourth edition.

Edward F. Goljan, MD
“Poppie”

vii
This page intentionally left blank
 Contents

CHAPTER 1 Diagnostic Testing   1

CHAPTER 2 Cell Injury   8

CHAPTER 3 Inflammation and Repair   36

CHAPTER 4 Immunopathology   56

CHAPTER 5 Water, Electrolyte, Acid-Base, and Hemodynamic
Disorders   93
CHAPTER 6 Genetic and Developmental Disorders   126

CHAPTER 7 Environmental Pathology   158

CHAPTER 8 Nutritional Disorders   174

CHAPTER 9 Neoplasia   195

CHAPTER 10 Vascular Disorders   215

CHAPTER 11 Heart Disorders   239

CHAPTER 12 Red Blood Cell Disorders   279

CHAPTER 13 White Blood Cell Disorders   318

CHAPTER 14 Lymphoid Tissue Disorders   334

CHAPTER 15 Hemostasis Disorders   351

CHAPTER 16 Immunohematology Disorders   367

CHAPTER 17 Upper and Lower Respiratory Disorders   377

CHAPTER 18 Gastrointestinal Disorders   419

CHAPTER 19 Hepatobiliary and Pancreatic Disorders   467

CHAPTER 20 Kidney Disorders   500

CHAPTER 21 Lower Urinary Tract and Male Reproductive
Disorders   528
ix
x   Contents

CHAPTER 22 Female Reproductive Disorders and Breast
Disorders   547

CHAPTER 23 Endocrine Disorders   588

CHAPTER 24 Musculoskeletal and Soft Tissue Disorders   630

CHAPTER 25 Skin Disorders   659

CHAPTER 26 Nervous System and Special Sensory Disorders   690

APPENDIX Formulas for Calculations of Acid-Base
Disorders   732
Index   734
 CHAPTER

1 Diagnostic Testing

Purpose of Laboratory Tests, 1 Creating Highly Sensitive and Specific Tests, 3
Operating Characteristics of Laboratory Tests, 2 Variables Affecting Laboratory Test Results, 3
Predictive Value of Positive and Negative Test
Results, 2

I. Purpose of Laboratory Tests
A. Screen for disease
1. General criteria for screening
a. Effective therapy that is safe and inexpensive must be available.
b. Disease must have a high enough prevalence to justify the expense.
Criteria for screening
c. Disease should be detectable before symptoms surface in the patient. test: ↑sensitivity and
d. Test must not have many false positives (people misclassified as having disease). prevalence; cost-
e. Test must have extremely high sensitivity. effective; treatable
2. Examples of screening tests
a. Newborn screening for inborn errors of metabolism
Examples—phenylketonuria, galactosemia, congenital hypothyroidism, and maple
syrup urine disease
b. Adult screening tests Cervical Pap: overall
(1) Mammography for breast cancer best screening test for
(2) Cervical Papanicolaou (Pap) smear for cervical cancer cancer
(3) Screen for human papillomavirus DNA
(4) Colonoscopy to detect/remove precancerous polyps
(5) Fecal occult blood testing to detect colon cancer
(6) Prostate-specific antigen (PSA) to detect prostate cancer
Currently, there is debate over the usefulness of this test.
(7) Bone densitometry scans to detect osteoporosis in women
(8) Fasting lipid profiles to evaluate coronary artery risk
Includes total cholesterol, high-density–lipoprotein cholesterol, low-density
lipoprotein, and total triglyceride
(9) Fasting blood glucose or 2-hour oral glucose tolerance test to screen for
diabetes mellitus
c. Screening people with symptoms of a disease
Example—serum antinuclear antibody test to rule out autoimmune disease
B. Confirm disease; examples:
1. Anti-Smith and double-stranded DNA antibodies to confirm systemic lupus
erythematosus
2. Chest x-ray to confirm pneumonia
3. Urine culture to confirm a urinary tract infection
4. Serum troponins I and T to confirm an acute myocardial infarction (AMI) Confirm disease: serum
5. Tissue biopsy to confirm cancer troponins to diagnose
6. Fluorescent treponemal antibody absorption test to confirm syphilis AMI
C. Monitor disease status; examples:
1. Hemoglobin (Hb) AIc to evaluate long-term glycemic control in diabetics
2. International normalized ratio (INR) to monitor warfarin therapy
(anticoagulation)
3. Therapeutic drug monitoring to ensure drug levels are in the optimal range Monitor disease: HbA1c,
4. Pulse oximeter to monitor oxygen saturation during anesthesia, asthmatic attacks INR, pulse oximeter

1
 2   Rapid Review Pathology

Test result Disease No disease

+ Test True positive(TP) False positive (FP)

– Test False negative (FN) True negative (TN)

1-1: People with disease either have true positive (TP) or false negative (FN) test results. People without disease
either have true negative (TN) or false positive (FP) test results.

II. Operating Characteristics of Laboratory Tests
A. Terms for test results for people with a specific disease (Fig. 1-1)
1. True positive (TP)
Definition—number of people with a specific disease who have a positive test result
Test results in people 2. False negative (FN)
with disease: TP and FN Definition—number of people with a specific disease who have a negative test result
B. Terms for test results for people without disease (see Fig. 1-1)
1. True negative (TN)
Test results in people Definition—number of people without disease who have a negative test result
without disease: TN 2. False positive (FP)
and FP Definition—number of people without disease who have a positive test result
C. Sensitivity of a test
1. Sensitivity of a test is obtained by performing the test on people that are known to have the
specific disease for which the test is intended (e.g., systemic lupus erythematosus [SLE]).
Sensitivity = TP ÷ (TP + 2. Definition—likelihood that a person with disease will have a positive test result
FN); “positivity” in 3. Formula for calculating sensitivity is TP ÷ (TP + FN).
disease The FN rate determines the test’s sensitivity.
4. Usefulness of a test with 100% sensitivity (no FNs)
a. Normal test result excludes disease (must be a TN).
Test with 100% b. Positive test result includes all people with disease.
sensitivity: normal result (1) Positive test result does not confirm disease.
TN; positive result TP (2) Positive test result could be a TP or a FP.
or FP c. Tests with 100% sensitivity are primarily used to screen for disease.
D. Specificity of a test
1. Specificity of a test is obtained by performing the test on people who do not have the
specific disease for which the test is intended.
Control group should include people of various ages and both sexes, and those who have
diseases that are closely related to the disease for which the test is intended.
Specificity = TN ÷ (TN + 2. Definition—likelihood that a person without disease will have a negative test result
FP); “negativity” in 3. Formula for calculating specificity is TN ÷ (TN + FP).
health FP rate determines the test’s specificity.
4. Usefulness for a test with 100% specificity (no FPs)
Test with 100%
specificity: positive test
a. Positive test result confirms disease (must be a TP).
TP; negative test TN b. Negative test result does not exclude disease, because a test result could be a TN or a FN.
or FN E. Comments on using tests with high sensitivity and specificity
1. When a test with 100% sensitivity (or close to it) returns negative (normal) on a patient on
Usefulness of test with one or more occasion, the disease can be excluded from the differential list.
100% sensitivity: For example, if the serum antinuclear antibody (ANA) test returns negative on more than
exclude disease when one occasion, the diagnosis of SLE can be excluded.
test returns normal 2. When a test with 100% sensitivity returns positive on a patient, a test with 100% specificity
(or close to it) should be used to decide if the test result was a TP or a FP.
Usefulness of test with a. For example if the serum ANA returns positive in a patient who is suspected of having
100% specificity:
distinguish TP from FP
SLE, the serum anti-Smith (Sm) and anti–double-stranded DNA test should be used
test result because they both have extremely high specificity for diagnosing SLE.
b. If either or both tests return positive, the patient has SLE.
c. If both tests consistently return negative, the patient most likely does not have SLE but
some other closely related disease.
III. Predictive Value of Positive and Negative Test Results
A. Predictive value of a negative test result (PV−)
1. Definition—likelihood that a negative test result is a TN rather than a FN
2. Formula for calculating PV− is TN ÷ (TN + FN).
PV− best reflects the true FN rate of a test.
 Diagnostic Testing   3

Prevalence of disease PV– PV+

Low prevalence of disease Increases (TN > FN) Decreases (FP > TP)

High prevalence of disease Decreases (FN > TN) Increases (TP > FP)

1-2: Note that in a low prevalence situation (e.g., ambulatory population), the PV− increases, while the PV+
decreases. The reverse occurs in a high prevalence situation (e.g., cardiac clinic) in that the PV− decreases and
the PV+ increases.

3. Tests with 100% sensitivity (no FNs) always have a PV− of 100%. Sensitivity 100% →
Disease is excluded from the differential list. PV− 100% → excludes
B. Predictive value of a positive test result (PV+) disease
1. Definition—likelihood that a positive test result is a TP rather than a FP
2. Formula for calculating PV+ is TP ÷ (TP + FP).
PV+ best reflects the true FP rate of a test. Specificity 100% →
3. Tests with 100% specificity (no FPs) always have a PV+ of 100%. PV+ 100% → confirms
Disease is confirmed. disease
C. Effect of prevalence on PV− and PV+
1. Definition—total number of people with disease in the population under study Prevalence: total #
Population includes people with disease and people without disease. people with disease in a
2. To calculate prevalence, people with disease are in the numerator (TP + FN) and people population
with disease (TP + FN) and without disease (TN + FP) are in the denominator. Prevalence: (TP + FN) ÷
(TP + FN) ÷ (TP + FN + TN + FP) (TP + FN + TN + FP)
3. Low prevalence of disease (e.g., ambulatory population) (Figs. 1-2 and 1-3)
a. PV− increases because more TNs are present than FNs. ↓Prevalence of disease:
b. PV+ decreases because more FPs are present than TPs. ↑PV−, ↓PV+
4. High prevalence of disease (e.g., cardiac clinic) (see Figs. 1-2 and 1-3)
a. PV− decreases because more FNs are present than TNs. ↑Prevalence of disease:
b. PV+ increases because more TPs are present than FPs. ↓PV−, ↑PV+
IV. Creating Highly Sensitive and Specific Tests
A. Ideal test (Fig. 1-4A)
1. Ideal test has 100% sensitivity (PV− 100%) and 100% specificity (PV+ 100%).
2. Note in the schematic that there are no FNs or FPs, because there is no overlap between the
normal and disease population. Serum troponins:
3. Ideal test is nonexistent; however, there are some tests that have very high sensitivity and ↑sensitivity and
specificity that come close to being the ideal test (e.g., serum levels of troponins I and T in specificity; screen/
diagnosing an AMI). confirm AMI
4. Most normal ranges (reference intervals) do not distinguish the normal from the disease
population (see Fig. 1-4B and C).
Note that there is an overlap between the normal and the disease population in parts B
and C of Figure 1-4.
B. Establishing a test with 100% sensitivity and PV− (see Fig. 1-4B)
1. To establish a test with 100% sensitivity and PV−, set the cutoff point for the reference
interval at the beginning of the disease curve (A). ↑Sensitivity/PV−: put
a. Note that this creates a test with 100% sensitivity and 100% PV−, because there are no cutoff point at the
FNs within the newly established reference interval (0 to A). beginning of the disease
b. Test can now be used to screen for disease. curve; no FNs
2. Note that by increasing sensitivity there is always a corresponding decrease in the specificity
and PV+ due to a greater number of FPs.
C. Establishing a test with 100% specificity and PV+ (see Fig. 1-4C)
1. To establish a test with 100% specificity/PV+, set the upper cutoff point for the reference
interval at the end of the normal curve (B).
↑Specificity/PV+: put
a. Note that this creates a test with 100% specificity and 100% PV+, because there are no cutoff point at the end
FPs outside the reference interval (0 to B). of the normal curve;
b. Test can now be used to confirm disease. no FPs
2. Note that by increasing specificity there is always a corresponding decrease in sensitivity and
PV−, due to a greater number of FNs.
V. Variables Affecting Laboratory Test Results
A. Premature newborns
1. Variable hemoglobin (Hb) concentration depending on the gestational age
 4   Rapid Review Pathology
A. Effect of low prevalence of systemic lupus erythematosus (SLE) on PV– and PV+
Sensitivity of serum ANA for SLE 100%
Specificity of serum ANA for SLE 80%
Prevalence of SLE is 1%
Population under study 1000
10 True positive (TP)
Number of people with SLE = 1000 x 0.01 = 10 x 100% sensitivity
0 False negative (FN)

792 True negative (TN)
Number of people without SLE = 990 x 80% specificity
198 False positive (FP)

SLE Control group

Positive test result 10 TP 198 FP
Negative test result 0 FN 792 TN
Total number 10 990

PV+ = 10 (TP) ÷ [10 (TP) + 198 (FP)] = ~ 5% (100 – 5 = 95% FP rate)
PV– = 792 (TN) ÷ [792 (TN) + 0 (FN)] = 100% (100 – 0 = 100% FN rate)

B. Effect of high prevalence of systemic lupus erythematosus (SLE) on PV– and PV+
Sensitivity of serum ANA for SLE 100%
Specificity of serum ANA for SLE 80%
Prevalence of SLE is 50%
Population under study 1000
500 True positive (TP)
Number of people with SLE = 1000 x 0.50 = 500 x 100% sensitivity
0 False negative (FN)

400 True negative (TN)
Number of people without SLE = 500 x 80% specificity
100 False positive (FP)

SLE Control group

Positive test result 500 TP 100 FP
Negative test result 0 FN 400 TN
Total number 500 500

PV+ = 500 (TP) ÷ [500 (TP) + 100 (FP)] = ~ 83% (100 – 83 = 17% FP rate)
PV– = 400 (TN) ÷ [400 (TN) + 0 (FN)] = 100% (100 – 0 = 100% FN rate)
1-3: Note how the PV− remained the same in both prevalence situations because of the 100% sensitivity of the
serum antinuclear antibody (ANA) for systemic lupus erythematosus (SLE). However, the PV+ significantly changed,
going from a low prevalence of SLE (~5%) to a high prevalence of SLE (~83%).

Anemia prematurity: 2. Anemia in prematurity is due to:
loss of iron from a. Iron deficiency, related to loss of the daily supply of iron from the mother’s iron stores
mother; blood loss from b. Blood loss from excessive venipunctures in the premature newborn
venipuncture
B. Newborns
1. Newborns have higher normal ranges for Hb, Hct, and RBC counts than do infants and
children.
2. HbF (2α/2γ globin chains) shifts the OBC to the left causing the release of EPO.
EPO causes an increase in Hb, Hct, and the RBC count.
3. Over the ensuing 8 to 12 weeks after birth, the Hb drops from 16.8 g/dL (range 14−20 g/dL)
to 11 g/dL (this is called physiologic anemia).
 Diagnostic Testing   5
1-4: Establishing tests with 100% sensitivity and
A specificity. Schematic A shows an ideal test with
Normal Disease 100% sensitivity (100% PV−) and 100% specificity
Number of

(100% PV+) when the normal range is 0 to A. Test
people

TN TP results below the A cutoff point are all true nega-
tives (TN), whereas those beyond the A cutoff point
TN TN TP TP are all true positives (TP). Schematic B shows a test
0 with 100% sensitivity (100% PV−) when the upper
A cutoff point is at A. Note that as sensitivity increases,
the specificity and PV+ decrease because of an
100% sensitivity 100% specificity increase in false positives (FP). Schematic C shows a
PV– 100% PV+ 100% test with 100% specificity (100% PV+) when the
upper cutoff point is at B. Note that as specificity
increases, the sensitivity and PV− decrease because
B of an increase in false negatives (FN). PV−, Predic-
Normal Disease tive value of a negative test result; PV+, predictive
Number of

value of a positive test result. (From Goljan E, Sloka
people

K: Rapid Review Laboratory Testing in Clinical Medicine,
TN Philadelphia, Mosby Elsevier, 2008, p 5, Fig. 1-3.)
FP TP
TP
TN TN FP TP TP
0 A B

100% sensitivity
PV– 100%

C
Normal Disease
Number of
people

TP
TN FN
TN
TN TN FN TP TP
0 A B

100% specificity
PV+ 100%

Fetal RBCs containing HbF are destroyed by splenic macrophages. The unconjugated bilirubin
derived from the initial destruction of fetal RBCs is responsible for physiologic jaundice of the
newborn, which occurs ~3 days after birth.

4. HbF–containing cells are replaced by RBCs containing HbA (>97%), HbA2 (2.0%), and Newborns: ↑HbF → left
HbF (1%). shift OBC → ↑EPO →
5. Immunoglobulin (Ig) synthesis ↑Hb, Hct, and RBC
production
a. Synthesis of IgM begins shortly after birth.
b. Newborns lack IgM isohemagglutinins (natural antibodies against blood groups) in their
plasma.
For example, blood group A newborns lack anti-B IgM isohemagglutinin in their
plasma.

Newborns: lack IgM at
Clinical correlation: Newborns with an increase in cord blood IgM may have an underlying
birth; ↑cord blood IgM
congenital infection (e.g., cytomegalovirus, rubella). Their blood should be screened for antibodies
indicates congenital
against the common congenital infections. infection

6. IgG antibodies in newborns are of maternal origin.
a. Newborns begin synthesizing IgG 2-3 months after birth.
b. Adult levels of IgG are achieved by age 6 to 10 years.

Clinical correlation: A mother with a positive test for human immunodeficiency virus (e.g., IgG Newborns normally
antibodies against the glycoprotein gp120) transplacentally transfers IgG antibodies to the fetus. synthesize both IgM
This does not mean that the child is infected by the virus. and IgG after birth
 6   Rapid Review Pathology
C. Children
1. When compared to an adult, children have higher serum alkaline phosphatase (ALP) levels.
a. This is due to increased bone growth in children and release of ALP from osteoblasts.
b. ALP removes the phosphate from pyrophosphate, which normally inhibits bone
mineralization.
2. When compared to an adult, children have higher serum phosphorus levels.
For normal mineralization of bone to occur, phosphorus is required to drive calcium into
bone; hence, the higher phosphorus levels in children.
3. When compared to an adult, children have a lower Hb concentration (11.5 g/dL; anemia

the circulating pool. circulating pool
(1) Circulating pool is located in the central axial stream of blood flowing through small
blood vessels. Neutrophil distribution:
(2) In a complete blood cell count (CBC), the circulating pool is counted and evaluated altered by activating/
inactivating adhesion
in a peripheral blood smear. molecules
c. Neutrophil distribution in these pools can be altered by activating or inactivating
neutrophil adhesion molecules (see later).
2. Margination of neutrophils
a. In AI, RBCs aggregate into rouleaux (“stacks of coins”) in the venules.
Caused by fibrinogen released from the liver
 38   Rapid Review Pathology

3-4: Acute inflammation. Histologic section of lung in bronchopneumonia showing sheets of neutrophils
with multilobed nuclei. The pink staining material in between the neutrophils is an exudate, which is protein-
and cell-rich fluid that is characteristic of AI. (From Damjanov I: Pathology for the Health-Related Professions, 2nd ed,
Philadelphia, Saunders, 2000, p 182, Fig. 8-8.)

b. Rouleau mechanically forces neutrophils out of the central axial stream and pushes them
to the periphery (called margination).
Margination: neutrophils Caution: margination of neutrophils is not the same as the marginating pool of
pushed to periphery
neutrophils.
Selectins: carbohydrate- 3. Rolling of neutrophils
binding adhesion a. Rolling occurs in venules and is due to expression of selectin adhesion molecules on
molecules neutrophils and venular endothelial cells.
b. Selectins are carbohydrate-binding adhesion molecules.
L-selectin: selectin c. L-Selectin is located on leukocytes (e.g., neutrophils), whereas E-selectin and P-selectin
ligand on leukocytes
are located on the surface of venular endothelial cells.
E-selectin: selectin (1) P-selectin is produced in the Weibel-Palade bodies in venular endothelial cells.
molecule on endothelial (2) Weibel-Palade bodies are the “glue factory” of endothelial cells, because they
cells synthesize P-selectin, an adhesion molecule for leukocytes, and von Willebrand
factor, the adhesion molecule of the platelet (refer to Chapter 15).
P-selectin: derived from d. Interleukin-1 (IL-1) and tumor necrosis factor (TNF) stimulate the expression of selectin
Weibel-Palade bodies in
ligands on the surface of neutrophils (L-selectin) and the expression of selectin molecules
endothelial cells
on the surface of venular endothelial cells (E-selectin, P-selectin; Fig. 3-5).
Weibel-Palade bodies: e. Binding of circulating neutrophils to E-selectin and P-selectin on venular endothelial
“glue factory” in cells is weak and transient, causing them to “roll” (bind−detach, bind−detach) along the
endothelial cells; surface.
selectins 4. Firm adhesion in venules is due to neutrophil expression of β2-integrins and venular
endothelial cell expression of integrin adhesion molecules (ligands).
Selectins activated by
IL-1 and TNF a. Activation of neutrophil β2-integrin (CD11a:CD18) adhesion molecules
(1) β2-integrins are located on neutrophils and interact with corresponding ligands on
Selectin adhesion: venular endothelial cells (see later; see Fig. 3-5).
“rolling” (bind−detach) (2) β2-Integrins on neutrophils are activated by C5a and leukotriene B4 (LTB4).
of neutrophils (3) Catecholamines and corticosteroids inhibit activation of these neutrophil adhesion
molecules.
β2-Integrins: firm
adhesion of neutrophils;
(a) Inhibition of neutrophil β2-integrins, leads to an increase in the peripheral blood
activated by C5a/LTB4 neutrophil count (called neutrophilic leukocytosis).
(b) This occurs because the normal marginating pool becomes part of the circulating
Catecholamines and pool, since they can no longer adhere to venular endothelium.
corticosteroids (4) Endotoxins enhance activation of neutrophil β2-integrins.
inactivate neutrophil (a) Enhanced activation of neutrophil β2-integrins causes the total circulating
β2-integrins: produces
neutrophilic leukocytosis
neutrophil count to decrease (called neutropenia).
(b) This occurs because the normal circulating neutrophil pool becomes part of the
Endotoxins activate marginating neutrophil pool.
neutrophil β2-integrins: b. Activation of endothelial cell integrin adhesion molecules (ligands)
produces neutropenia (1) IL-1 and TNF activate intercellular adhesion molecule (ICAM) and vascular cell
adhesion molecule (VCAM) on venular endothelial cells.
ICAM/VCAM:
(2) Activated ICAM ligands bind to activated β2-integrins on neutrophils causing them
endothelial cell integrin
adhesion molecules to firmly adhere to venular endothelium.
(ligands); activated by (3) Activated VCAM ligands firmly bind to activated β1-integrins on eosinophils,
IL-1/TNF monocytes, and lymphocytes.
 Inflammation and Repair   39

Integrin Migration
activation by Stable
Rolling through
chemokines adhesion
endothelium
Leukocyte Integrin
(low-affinity state)
Integrin (high-
Selectin ligand affinity state)

Chemokine PECAM-1
(CD31)
Selectin

Proteo- Integrin
glycan ligand

Chemokines
Cytokines
(TNF, IL-1) Macrophage
with microbes Fibrin and fibronectin
(extracellular matrix)
3-5: The sequence of events in the migration of blood leukocytes to sites of infection. At sites of infection,
macrophages and dendritic cells that have encountered microbes produce cytokines (e.g., tumor necrosis factor
[TNF] and interleukin-1 [IL-1]) that activate the endothelial cells of nearby venules to produce selectins, ligands
for integrins, and chemokines. Selectins mediate weak tethering and rolling of blood neutrophils on the endo-
thelium; integrins mediate firm adhesion of neutrophils; and, chemokines activate the neutrophils and stimulate
their migration through the endothelium to the site of infection. Blood monocytes and activated T lymphocytes
use the same mechanisms to migrate to sites of infection. PECAM-1, Platelet-endothelial cell adhesion molecule-1.
(From Abbas A, Lichtman A: Basic Immunology Updated Edition: Function and Disorders of the Immune System, 3rd ed,
Philadelphia, Saunders Elsevier, 2010, p 30, Fig. 2-7.)

c. Leukocyte adhesion deficiency (LAD) disorders
(1) Autosomal recessive inheritance pattern
(2) LAD type 1 is a deficiency of β2-integrin (CD11a:CD18). Delayed separation of
CD stands for cluster of designation. umbilical cord: LAD due
(3) LAD type 2 is a deficiency of an endothelial cell selectin that normally binds to selectin or CD11a/
neutrophils. CD18 deficiency
(4) Clinical findings
(a) First manifestation in either type is delayed separation of the umbilical cord
(usually separates and sloughs by the end of the second postnatal week).
Neutrophil enzymes are important in cord separation; therefore in a histologic
section of the surgically removed umbilical cord, no neutrophils would be seen
adhering to venular endothelium or be seen in the interstitial tissue.
Transmigration
(b) Additional clinical findings include severe gingivitis, poor wound healing, and (diapedesis): movement
peripheral blood neutrophilic leukocytosis (loss of the marginating pool). of neutrophils from
5. Transmigration (diapedesis) of neutrophils venules into interstitial
a. Neutrophils moving along the venular endothelium dissolve the venular basement space
membrane (release type IV collagenase) exposed by previous histamine-mediated
endothelial cell contraction and enter the interstitial tissue. Exudate: protein- and
cell-rich fluid (pus)
b. Plasma-derived fluid rich in proteins and cells (i.e., exudate, pus) accumulates in the
interstitial tissue. Exudate: dilutes
c. Functions of exudate bacterial toxins;
(1) Dilutes bacterial toxins, if they are present provides opsonins
(2) Provides opsonins (IgG, C3b) to assist in phagocytosis (see later)
6. Chemotaxis of neutrophils Chemotaxis: directed
migration of neutrophils
a. Neutrophils follow chemical gradients that lead to the infection site.
b. Chemotactic mediators bind to neutrophil receptors. Chemotaxis mediators:
Mediators include C5a, LTB4, bacterial products, and interleukin (IL)-8. C5a, LTB4, bacterial
c. Binding causes the release of calcium, which increases neutrophil motility. products, IL-8
 40   Rapid Review Pathology

Bacteria
IgG (opsonin) Bacteria
O2 Respiratory
Fc receptor NADPH burst C3b (opsonin)
NADPH oxidase
Neutrophil complex C3b
cell membrane NADP+ –
O2 (superoxide) receptor

Deficient in CGD SOD
H2O2 H O H2O
+ Fe 2+ Fenton reaction 2 2
–
GSH peroxidase
Hydrolases Cl OH GSH GSSG
ria MPO
a cte
B HOCl (bleach) NADP+ NADPH
Phagolysosome
Cofactor for
MPO NADPH
Hydrolases G6-P 6PG oxidase
MPO Glucose-6-phosphate
Bacteria
dehydrogenase

3-6: O2-dependent myeloperoxidase system. A series of biochemical reactions occurs in the phagolysosome,
resulting in the production of hypochlorous free radicals (bleach; HOCl ) that destroy bacteria. Conversion of
H2O2 to OH using reduced Fe2+ as a source of electrons is called the Fenton reaction. NADPH produced by the
pentose phosphate shunt is a cofactor for NADPH oxidase, which is deficient in CGD. A decrease in the cofactor
NADPH (i.e., glucose-6-phosphate dehydrogenase deficiency) also interferes with the normal functioning of
the O2-dependent MPO system. IgG and C3b are opsonins that facilitate the actions of phagocytic leukocytes
(neutrophils, monocytes). CGD, Chronic granulomatous disease; Fe2+, reduced iron; GSH, reduced glutathione;
G6-P, glucose 6-phosphate; GSSG, oxidized glutathione; H2O2, peroxide; MPO, myeloperoxidase; NADP, oxidized
form of nicotinamide adenine dinucleotide phosphate; NADPH, reduced nicotinamide adenine dinucleotide
phosphate; OH , hydroxyl free radical; 6PG, 6-phosphogluconate; SOD, superoxide dismutase.

7. Neutrophil phagocytosis (Fig. 3-6)
a. Neutrophil phagocytosis is a multistep process, consisting of opsonization, ingestion, and
killing.
Opsonins: IgG and C3b;
b. Neutrophil opsonization
enhance neutrophil
ability to ingest bacteria (1) Opsonins attach to bacteria (or foreign bodies).
(a) Opsonins include IgG, the C3b fragment of complement, and other proteins
Opsonins: IgG and C3b; (e.g., C-reactive protein).
enhance neutrophil (b) Neutrophils have membrane receptors for IgG and C3b.
recognition and (2) Opsonization enhances neutrophil recognition and attachment to bacteria (and
attachment of bacteria foreign bodies).
Bruton (3) Bruton agammaglobulinemia is an opsonization defect (refer to Chapter 4).
agammaglobulinemia: In Bruton agammaglobulinemia, pre–B cells cannot mature to B cells; therefore
opsonization defect plasma cells, which are derived from B cells, cannot synthesize immunoglobulins
(lack of IgG) (i.e., IgG).
c. Neutrophil ingestion
Neutrophil ingestion: (1) Neutrophils engulf (phagocytose) and then trap bacteria in phagocytic vacuoles
phagosome →
phagolysosome (phagosomes).
(2) Primary lysosomes empty hydrolytic enzymes into phagocytic vacuoles producing
Chédiak-Higashi phagolysosomes.
syndrome: cannot form In Chédiak-Higashi syndrome (refer to Chapter 2), there is a defect in microtubule
phagolysosomes function, which prevents lysosomes from fusing with phagosomes to produce a
phagolysosome.
MPO: neutrophil/
monocyte lysosomal
d. Neutrophil killing of bacteria/fungi by the O2-dependent myeloperoxidase (MPO) system
enzyme (see Fig. 3-6)
(1) O2-dependent MPO system only present in neutrophils and monocytes (not
O2-dependent MPO macrophages)
system: most potent MPO is a neutrophil/monocyte lysosomal enzyme.
microbicidal system (2) MPO system most potent microbicidal system available to neutrophils and
NADPH oxidase enzyme
monocytes
complex: converts (3) Production of superoxide free radicals (FRs)
molecular O2 to NADPH oxidase enzyme complex converts molecular O2 to superoxide FRs, which
superoxide FRs releases energy called the respiratory, or oxidative, burst.
 Inflammation and Repair   41
(4) Production of peroxide (H2O2) SOD converts
(a) Superoxide dismutase (SOD) converts O2 – to H2O2. superoxide free radicals
(b) Some peroxide is converted to hydroxyl FRs by iron via the Fenton reaction to H2O2
(refer to Chapter 2). End-product O2-
(5) Production of bleach (HOCl ) dependent MPO system:
MPO in the phagolysosome combines H2O2 with chloride (Cl–) to form bleach
hypochlorous FRs (HOCl ), which kill bacteria and some fungi.
(6) Chronic granulomatous disease (CGD) and MPO deficiency are examples of diseases
that have a defect in the O2-dependent MPO system.

Chronic granulomatous disease (CGD) is an X-linked recessive disorder (65% of cases) or
autosomal recessive disorder (30% of cases). The X-linked type is characterized by a mutation in
the CYBB gene that encodes for a component in the NADPH oxidase enzyme complex (PHOX
system) rendering the complex dysfunctional. The reduced production of O2 – results in an absent
respiratory (oxidative) burst. Catalase-positive organisms that produce H2O2 (e.g., Staphylococcus
aureus, Nocardia asteroides, Serratia marcescens, Aspergillus species, and Candida species) are
ingested but not killed, because the catalase degrades the H2O2 produced by these pathogens.
Myeloperoxidase is present, but HOCl is not synthesized because of the absence of H2O2.
However, catalase-negative organisms (e.g., Streptococcus species) that produce H2O2 are ingested
and can be killed when myeloperoxidase combines H2O2 (derived from the bacteria) with Cl– to
form HOCl. Granulomatous inflammation occurs in tissue, because the neutrophils, which can
phagocytose bacteria but not kill most of them, are eventually replaced by cells associated with
chronic inflammation, mainly lymphocytes and macrophages. Macrophages fuse to form
multinucleated giant cells, which is a characteristic feature of granulomatous inflammation.
Patients with CGD have severe infections involving the lungs (pneumonia is the most common
presentation), skin, visceral organs, and bones. The classic screening test for CGD is the nitroblue
tetrazolium (NBT) dye test. In this test, leukocytes in a test tube are incubated with the NBT dye,
which turns blue if superoxide FRs are present, indicating that the respiratory (oxidative) burst is
intact (considered to be a positive test). The NBT dye test is negative in the X-linked type of CGD
(NBT dye is not converted to a blue dye), because the NADPH oxidase enzyme complex is
dysfunctional. Because of its lack of sensitivity, the NBT dye test has essentially been replaced by a
more sensitive test involving oxidation of dihydrorhodamine to fluorescent rhodamine, which is
abnormal in both variants of CGD. Treatment of CGD involves prophylaxis and treatment of
infections and bone marrow transplantation.
Myeloperoxidase (MPO) deficiency differs from CGD in that both O2 – and H2O2 are produced
(normal respiratory burst). However, the absence of MPO prevents synthesis of HOCl.

(7) Deficiency of NADPH (e.g., glucose-6-phosphate dehydrogenase [G6PD] deficiency)
produces a microbicidal defect.
(a) NADPH is a cofactor for the NADPH oxidase complex; therefore absence of
G6PD deficiency: lack of
NADPH in G6PD deficiency, a hemolytic anemia (refer to Chapter 12), renders NADPH interferes with
the enzyme nonfunctional. normal function of the
(b) Patients with G6PD deficiency are very susceptible to bacterial and certain O2-dependent MPO
fungal infections because the O2-dependent MPO system is dysfunctional. system
(8) Table 3-1 compares CGD and MPO deficiency.
e. Neutrophil killing of bacteria by O2-independent microbial systems O2-independent systems:
(1) Oxygen-independent systems for killing bacteria refer to the release of lethal lactoferrin (neutrophils),
substances that are located in leukocyte granules. MBP (eosinophils)
(2) Examples include:
(a) Lactoferrin (present in neutrophil granules), which binds iron that is necessary
for normal bacterial growth and reproduction
(b) Major basic protein (MBP), an eosinophil product that is cytotoxic to Histamine: most
helminths important chemical
mediator of AI
F. Chemical mediators in AI (Table 3-2)
1. Chemical mediators derive from plasma, leukocytes, local tissue, and bacterial products.
Example—arachidonic acid mediators are released from membrane phospholipids in
macrophages, endothelial cells, and platelets (Fig. 3-7)
2. Short half-lives (e.g., seconds to minutes)
3. May have local and systemic effects
Example—histamine may produce local signs of itching or systemic signs of anaphylaxis
42   Rapid Review Pathology
TABLE 3-1 Comparison of Chronic Granulomatous Disease and
Myeloperoxidase Deficiency
CHRONIC
GRANULOMATOUS MYELOPEROXIDASE
DISEASE DEFICIENCY
Inheritance pattern X-linked recessive Autosomal recessive
NADPH oxidase Absent Present
Myeloperoxidase Present Absent
Respiratory burst Absent Present
Peroxide (H2O2) Absent Present
Bleach (HOCl) Absent Absent

TABLE 3-2 Sources and Functions of Chemical Mediators
MEDIATOR SOURCE(S) FUNCTION(S)
Arachidonic Acid Metabolites
Prostaglandins Macrophages, endothelial cells, PGE2: vasodilation, pain, fever
platelets
PGH2: major precursor of PGs and PGI2: vasodilation; inhibition of platelet
thromboxanes aggregation
Thromboxane A2 Platelets Vasoconstriction, platelet aggregation
Converted from PGH2 by
thromboxane synthase
Leukotrienes (LTs) Leukocytes LTB4: chemotaxis and activation of
neutrophil adhesion molecules
Converted from arachidonic acid LTC4, LTD4, LTE4: vasoconstriction,
by lipoxygenase-mediated increased venular permeability,
hydroxylation bronchoconstriction
Zileuton inhibits 5-lipoxygenase:
↓synthesis LTB4, LTC4, LTD4, LTE4
Montelukast is a leukotriene receptor
antagonist: ↓activity of LTC4, LTD4,
LTE4
Bradykinin Product of kinin system activation Vasodilation, increased venular
by activated factor XII permeability, pain
Chemokines Leukocytes, endothelial cells Activate neutrophils and stimulate their
migration through the endothelium to
the site of infection (chemotaxis; see
Fig. 3-5)
Complement Synthesized in liver (acute phase C3a, C5a (anaphylatoxins): stimulate mast
reactant) cell release of histamine
C3b: opsonization
C5a: activation of neutrophil adhesion
molecules, chemotaxis
C5–C9 (membrane attack complex): cell
lysis
Cytokines
IL-1, TNF Macrophages (main source), Initiate PGE2 synthesis in the anterior
monocytes, dendritic cells, hypothalamus, leading to production of
endothelial cells fever
Activate endothelial cell adhesion
molecules
TNF is a promoter of apoptosis (refer to
Chapter 2)
IL-6 Primary cytokine responsible for increased
liver synthesis of acute phase reactants
(APRs), such as ferritin, coagulation
factors (e.g., fibrinogen), and C-reactive
protein
IL-8 Chemotaxis
Histamine Mast cells (primary cell), platelets, Vasodilation, increased venular
enterochromaffin cells permeability
Nitric Oxide (NO) Macrophages, endothelial cells Vasodilation, bactericidal
Free radical gas released during
conversion of arginine to
citrulline by NO synthase
IL, Interleukin; PG, prostaglandin; TNF, tumor necrosis factor.
 Inflammation and Repair   43

Cell membrane phospholipids
Phospholipase A2
Inhibited by corticosteroids
Linoleic acid
ω6 Arachidonic acid
5-Lipoxygenase Cyclooxygenase
Inhibited by Zileuton Inhibited by aspirin/NSAIDs

LTB4, LTC4, LTD4, LTE4 PGG2
Receptors inhibited by Montelukast
Thromboxane synthase Prostacyclin synthase
TXA2 PGH2 PGI2
Platelet Endothelial cell

PGE2 PGF2α

3-7: Simplified arachidonic acid metabolism. Arachidonic acid is released from membrane phospholipids by
phospholipase A2. It is converted into prostaglandins (PGs) and thromboxane A2 (TXA2) in platelets from PGH2,
the precursor prostaglandin, and into leukotrienes (LTs) by 5-lipoxygenase. Linoleic acid is an ω-6 essential fatty
acid that is used to synthesize arachidonic acid. Phospholipase A2 is inhibited by corticosteroids; 5-lipoxygenase,
by zileuton; receptors for LTC4, LTD4, LTE4, by montelukast; and cyclooxygenase (COX), by aspirin and NSAIDs. The
COX-1 isoform (not depicted) is constitutively expressed in various tissues, whereas the COX-2 isoform (not
depicted) is induced by various growth factors and proinflammatory cytokines. See text and Table 3-2 for further
discussion. NSAIDs, nonsteroidal antiinflammatory drugs; PGI2, prostacyclin.

4. Mediators have diverse functions including:
a. Vasodilation
Examples—histamine, nitric oxide, PGI2
b. Vasoconstriction
Example—thromboxane A2 (TXA2)
c. Increasing venular permeability
Examples—histamine, bradykinin, LTC4, LTD4, LTE4, C3a, and C5a (anaphylatoxins)
d. Producing pain
Examples—PGE2, bradykinin
e. Producing fever
Examples—PGE2, IL-1, TNF
f. Chemotaxis
Examples—C5a, LTB4, IL-8
g. Liver synthesis of acute phase reactants (APRs; e.g., fibrinogen, ferritin, complement,
hepcidin, C-reactive protein)
IL-6 stimulates APR synthesis.
G. Types of AI
1. Location, cause, and duration of inflammation determine the morphology of an
inflammatory reaction.
2. Purulent (suppurative) inflammation
a. Definition—localized proliferation of pus-forming organisms, such as S. aureus (e.g., skin
abscess; Fig. 3-8A).
b. S. aureus contains coagulase, which cleaves fibrinogen into fibrin and traps bacteria and S. aureus: most common
neutrophils, and therefore keeps the lesion localized. cause of a skin abscess
3. Fibrinous inflammation Fibrinous inflammation:
a. Definition—inflammation due to increased vessel permeability, with deposition of a exudate covering
fibrin-rich exudate on the surface of the tissue (see Fig. 3-8B). serosal surfaces (heart,
b. Commonly occurs on the serosal lining of the pericardium, peritoneum, or pleura. lungs, peritoneum)
(1) Friction rub may be heard over the precordium in fibrinous pericarditis associated
with a myocardial infarction or rheumatic fever (refer to Chapter 11).
(2) Friction rub may be heard over the precordium or lungs in fibrinous pleuritis
secondary to a pulmonary infarction or pneumonia (refer to Chapter 17).
(3) Small bowel obstruction from serosal adhesions between other loops of bowel may
occur from peritoneal irritation related to previous abdominal surgery (refer to
Chapter 18).
4. Serous inflammation
a. Definition—inflammation with a thin, watery exudate that has an insufficient amount of Serous inflammation:
fibrinogen to produce fibrin. thin watery exudate;
b. Examples—blister in second degree burns, viral pleuritis blister, viral pleuritis
 44   Rapid Review Pathology

A B C
3-8: A, Purulent (suppurative) inflammation. The photograph shows a skin abscess (furuncle) due to Staphylococcus aureus. Abscesses
are pus-filled nodules located in the dermis. Note the multiple draining sinus tracts filled with pus. B, Fibrinous inflammation. The surface
of the heart is covered by a shaggy, fibrinous exudate. C, Pseudomembranous inflammation. There is necrosis and a yellow-colored exudate
covering the mucosal surface of the colon due to a toxin produced by Clostridium difficile. (A from Bouloux P: Self-Assessment Picture Tests
Medicine, Vol. 1, London, Mosby-Wolfe, 1997, p 33, Fig. 66; B from Damjanov I, Linder J: Pathology: A Color Atlas, St. Louis, Mosby, 2000, p 25,
Fig. 1-59; C from Grieg J: Color Atlas of Surgical Diagnosis, London, Mosby-Wolfe, 1996, p 202, Fig. 26-10.)

Pseudomembranous 5. Pseudomembranous inflammation
inflammation: a. Definition—bacterial toxin–induced damage of the mucosal lining, producing a shaggy
diphtheria, Clostridium membrane composed of necrotic tissue.
difficile b. Examples include pseudomembranes associated with:
(1) Clostridium difficile, in pseudomembranous colitis (see Fig. 3-8C).
(2) Corynebacterium diphtheriae, which produces a toxin causing pseudomembrane
formation in the pharynx and trachea (see Fig. 17-5D).
H. Role of fever in AI
1. The O2-binding curve (OBC; refer to Chapter 2) is right-shifted.
Fever is beneficial: OBC
More O2 is available for the O2-dependent MPO system.
right-shifted, ↓bacterial/ 2. It provides a hostile environment for bacterial and viral reproduction.
viral reproduction 3. In hospitalized patients, fever is most commonly due to bacterial infections targeting the
respiratory tract, urinary tract, or skin and soft tissue.
I. Termination of AI
Chemical mediators 1. AI mediators have a short half-life.
have a short half-life.
2. Production of lipoxins (antiinflammatory mediators)
Lipoxins: inhibit a. Derive from arachidonic acid metabolites (e.g., LXA4, LXB4)
transmigration/ b. Inhibit transmigration and chemotaxis of neutrophils
chemotaxis; enhance c. Signal macrophages to phagocytose apoptotic bodies
apoptosis 3. Production of resolvins
a. Synthesized from ω-3 fatty acids
Resolvins: inhibit b. Inhibit production and recruitment of inflammatory cells to the site of AI
recruitment
inflammatory cells 4. Increased clearance of neutrophils by apoptosis
J. Consequences of AI
Neutrophils cleared 1. Complete resolution of AI
from the inflammatory a. Occurs with mild injury to cells that have the capacity to enter the cell cycle (e.g., labile
site by apoptosis and stable cells).
b. Examples—first-degree burn, bee sting
2. Tissue destruction and scar formation
a. Destruction of tissue and scar tissue occurs with extensive injury or damage to
permanent cells.
Consequences:
b. Examples—third-degree burns, acute myocardial infarction
resolution, scar tissue, 3. Formation of abscesses (localized collection of neutrophils with liquefactive necrosis)
abscess, progression to Example—lung abscess may develop after aspiration of oropharyngeal material
chronic inflammation 4. Progression of AI to chronic inflammation
II. Chronic Inflammation (CI)
A. Definition of CI
Prolonged inflammation (weeks to years) that most often results from persistence of an
injury-causing agent
Infection: most common B. Causes of CI
cause of chronic 1. Infection is the most common cause of CI.
inflammation Examples—tuberculosis (TB), leprosy, hepatitis C
 Inflammation and Repair   45

3-9: Chronic inflammation. This tissue shows an infil- 3-10: Granulation tissue. Note the mixture of acute
trate of predominantly lymphocytes and occasional (neutrophils) and chronic inflammatory cells (lympho-
plasma cells (cells with eccentric nuclei and perinuclear cytes, plasma cells, macrophages) intermixed with
clearing, white arrow). (From Damjanov I, Linder J: dilated, small vessels. Numerous, plump fibroblasts
Anderson’s Pathology, 10th ed, St. Louis, Mosby, 1996, (arrows) laying down type III collagen are also present.
p 390, Fig. 18-7B.) (From Damjanov I, Linder J: Anderson’s Pathology, 10th ed,
St. Louis, Mosby, 1996, p 436, Fig. 19-2B.)

2. Autoimmune disease
Examples—rheumatoid arthritis, systemic lupus erythematosus
3. Inflammatory reaction to sterile agents
Examples—silica, uric acid, silicone in breast implants
C. Morphology of CI Monocytes and/or
1. Cell types that define CI macrophages: primary
a. Monocytes and macrophages (key cells); lymphocytes, plasma cells, and eosinophils leukocytes in chronic
(Fig. 3-9). inflammation
b. Transforming growth factor (TGF)-β is chemotactic for macrophages, lymphocytes, and
fibroblasts.
2. Destruction of parenchyma
With loss of parenchyma, there is loss of functional tissue, with repair by fibrosis.
3. Formation of granulation tissue
a. Definition—highly vascular tissue composed of blood vessels and activated fibroblasts
(Fig. 3-10).
(1) Blood vessels derive from preexisting blood vessels and de novo from endothelial cell
precursors recruited from the bone marrow (i.e., angiogenesis). Granulation tissue:
blood vessels,
Important growth factors in angiogenesis—vascular endothelial cell growth factor,
fibroblasts
fibroblast growth factor, epidermal growth factor, platelet derived growth factor,
TGF-β Granulation tissue:
(2) Vascularization is essential for normal wound healing. precursor of scar tissue
(3) Granulation tissue is precursor of scar tissue.
b. Fibronectin is required for granulation tissue formation. Fibronectin: key
(1) Cell adhesion glycoprotein located in the extracellular matrix (ECM) adhesion glycoprotein in
ECM; chemotactic factor
It binds to collagen, fibrin, and cell surface receptors (e.g., integrins). for fibroblasts and
(2) Chemotactic factor that attracts fibroblasts (synthesize collagen) and endothelial cells endothelial cells
(form new blood vessels, angiogenesis)
4. Comparison table of AI and CI (Table 3-3) Granulomatous
5. Granulomatous inflammation inflammation:
a. Definition—specialized type of chronic inflammation specialized type of
chronic inflammation
b. Causes
(1) Infections Granulomatous
(a) Examples—TB and systemic fungal infection (e.g., histoplasmosis) infections: TB, systemic
(b) Infections caused by TB and systemic fungi are usually associated with caseous fungi (e.g.,
necrosis (i.e., soft granulomas; refer to Chapter 2). histoplasmosis)
Caseation is due to lipid released from the cell wall of dead pathogens.
Noninfectious
(2) Noninfectious causes granulomatous
(a) Examples—sarcoidosis and Crohn disease inflammation:
(b) Sarcoidosis and Crohn disease have noncaseating granulomas (i.e., hard sarcoidosis, Crohn
granulomas). disease
 46   Rapid Review Pathology
TABLE 3-3 Comparison of Acute and Chronic Inflammation
ACUTE INFLAMMATION CHRONIC INFLAMMATION
Pathogenesis Microbial pathogens, trauma, Persistent AI, foreign bodies (e.g.,
burns silicone, glass), autoimmune
disease, certain types of
infection (e.g., TB, leprosy)
Primary cells involved Neutrophils Monocytes/macrophages (key
cells), B and T lymphocytes,
plasma cells, fibroblasts
Primary mediators Histamine (key mediator), Cytokines (e.g., IL-1), growth
prostaglandins, leukotrienes factors
Necrosis Present Less prominent
Scar tissue Absent Present
Onset Immediate Delayed
Duration Few days Weeks, months, years
Outcome Complete resolution, progression Scar tissue formation, disability,
to chronic inflammation, amyloidosis (refer to Chapter 4)
abscess formation
Main immunoglobulin IgM IgG
SPE effect Mild hypoalbuminemia Polyclonal gammopathy; greater
degree of hypoalbuminemia
Peripheral blood leukocyte response Neutrophilic leukocytosis Monocytosis
AI, Acute inflammation; SPE, serum protein electrophoresis; TB, tuberculosis.

Cell types in tuberculous c. Morphology of a granuloma
granuloma: (1) Definition—pale, white nodule with or without central caseation
macrophages and CD4 (2) Usually well-circumscribed in tissue (see Fig. 2-15G)
helper T cells
(3) Cell types in an infectious granuloma (e.g., tuberculosis)
Epithelioid cells: (a) Epithelioid cells (activated macrophages) and mononuclear cells consisting of
macrophages activated CD4 helper T cells, specifically, TH cells of the TH1 type (memory T cells)
by interferon-γ from (b) Multinucleated giant cells formed by fusion of epithelioid cells
CD4 TH1 cells Multinucleated giant cell nuclei are usually located at the periphery of the
granuloma.
Multinucleated giant
cells: formed by fusion
(4) TNF-α is important in the formation and maintenance of TB and systemic fungal
of epithelioid cells granulomas.
(a) TNF-α and interferon-γ recruit cells for granuloma formation.
(b) TNF-α inhibitors cause the breakdown of granulomas, which may result in
dissemination of disease (e.g., disseminated TB).
(5) Specifics concerning the sequence of events in the formation of a granuloma are fully
discussed in Chapter 4 under type IV hypersensitivity reactions.
Tissue repair: III. Tissue Repair
parenchymal cell A. Factors involved in tissue repair
regeneration, repair by 1. Parenchymal cell regeneration
connective tissue
2. Repair by connective tissue (fibrosis)
Cell regeneration: only B. Parenchymal cell regeneration
labile and stable cell 1. Cell regeneration depends on the ability of cells to replicate (refer to Chapter 2).
can regenerate a. Labile cells (e.g., stem cells in epidermis) and stable cells (e.g., fibroblasts) can replicate.
b. Permanent cells cannot replicate.
Cell regeneration: Cardiac and striated muscle are replaced by scar tissue (fibrosis).
permanent cells cannot
regenerate
2. Cell regeneration depends on factors that stimulate parenchymal cell division and migration.
Stimulatory factors include loss of tissue and production of growth factors (Table 3-4).
3. Cell cycle (Fig. 3-11)
a. Phases
G0 phase: resting phase (1) G0 phase
of stable cells Resting phase of stable parenchymal cells
(2) G1 phase
G1 phase: most variable
phase in cell cycle
(a) Synthesis of RNA, protein, organelles, and cyclin D
(b) Most variable phase in the cell cycle
G1 phase: synthesis of (3) S (synthesis) phase
DNA, RNA, protein Synthesis of DNA, RNA, and protein.
 Inflammation and Repair   47
TABLE 3-4 Factors Involved in Tissue Repair
FACTOR FUNCTIONS
Growth Factors
Vascular endothelial cell growth factor Stimulates angiogenesis (embryonic angiogenesis, particularly in the
(VEGF) heart), repair of tissue, cancer angiogenesis (stimulates from
preexisting vessels)
Stimulation factors: TNF released by macrophages, hypoxia via
hypoxia-inducible factor released by cells
Fibroblast growth factor (FGF) Chemotactic for fibroblasts; stimulates keratinocyte migration,
angiogenesis, wound contraction
Epidermal growth factor (EGF) Stimulates keratinocyte migration, granulation tissue formation
Platelet-derived growth factor (PDGF) Chemotactic for neutrophils, macrophages, fibroblasts, endothelial
cells (angiogenesis), smooth muscle cells (angiogenesis)
Transforming growth factor-β (TGF-β) Chemotactic for macrophages, lymphocytes, fibroblasts, smooth
muscle cells (angiogenesis)
Interleukins (IL), Cytokines
IL-1 Stimulates synthesis of metalloproteinases (i.e., enzymes containing
trace metals)
Stimulates synthesis and release of acute phase reactants from the
liver
Tumor necrosis factor (TNF) Activates macrophages; stimulates release of acute phase reactants