"Pathoma 2023 PDF" Medical Textbook

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This is a medical textbook on pathology, specifically covering Fundamentals of Pathology. It's designed for medical students and as a review for exams like the USMLE. The book is organized to follow standard pathology course outlines.

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PATHOMA.COM
Fundamentals of Pathology : Medical Course and Step 1 Review

ISBN 978-0-9832246-3-l

Printed in the United States of America.

Copyright© 2023 by Pathoma LLC.

Previous editions copyrighted 2011, 2013, 2014, 2015, 2016, 2017, 2018,2019,2020,21,22

All rights reserved. No part of this publication may be reproduced, distributed, or
transmitted in any form, or by any means, electronic or mechanical, including
photocopying, recording, or any information storage and retrieval system, without prior
permission in writing from the publisher (email: [email protected]).

Disclaimer
Fundamentals of Pathology aims at providing general principles of pathology and its
associated disciplines and is not intended as a working guide to patient care, drug
administration or treatment. Medicine is a constantly evolving field and changes in practice
regularly occur. It is the responsibility of the treating practitioner, relying on independent
expertise and knowledge of the patient, to determine the best treatment and method of
application for the patient. Neither the publisher nor the author assume any liability for
any injury and/or damage to persons or property arising from or related to the material
within this publication.

Furthermore, although care has been taken to ensure the accuracy of information present
in this publication, the author and publisher make no representations or warranties
whatsoever, express or implied, with respect to the completeness, accuracy or currency of
the contents of this publication. This publication is not meant to be a substitute for the
advice of a physician or other licensed and qualified medical professional. Information
presented in this publication may refer to drugs, devices or techniques which are subject to
government regulation, and it is the responsibility of the treating practitioner to comply with
all applicable laws.

This book is printed on acid-free paper.

Published by Pathoma LLC.
http://www.pathoma.com
[email protected]

Cover and page design by Olaf Nelson, Chinook Design, Inc.
http://www.chinooktype.com
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CONTENTS
Chapter 1. Growth Adaptations, Cellular Injury, and Cell Death

1

Chapter 2. Inflammation, Inflammatory Disorders, and Wound Healing

11

Chapter 3. Principles of Neoplasia

23

Chapter 4. Hemostasis and Related Disorders

31

Chapter 5. Red Blood Cell Disorders

41

Chapter 6. White Blood Cell Disorders

53

Chapter 7. Vascular Pathology

65

Chapter 8. Cardiac Pathology

73

Chapter 9. Respira
espiratory
ory Tr
Tract
act Pathology

85

Chapter 10. Gastroin
astrointtestinal P
Paathology

99

Chapter 11. Exocrine
Ex ocrine Pancr
Pancreas
eas,, Gallbladder
Gallbladder,, and Liver
Liver P
Paathology.......

115
115

Chapter 12. Kidney
idney and Urinary
Urinary Tract
act Pa
Pathology

125

Chapter 13. Female Genital System and Gestational Pathology

137
»

Chapter 14. Male Genital System Pathology

151

Chapter 15. Endocrine Pathology

159

Chapter 16. Breast Pathology

175

Chapter 17. Central Nervous System Pathology

181

Chapter 18. Musculoskeletal Pathology

195

Chapter 19. Skin Pathology

205

Index................................................................. 213
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USING THIS BOOK
This work is intended as a review for students during their preclinical years and while
preparing for examinations, such as the USMLE. To this effect, the organization of this book
follows that of most primary texts in the field and parallels the syllabus used in
pathophysiology courses in medical schools throughout the United States. Ample space is
provided for students to make notes during course study and while viewing the online
videos that cover each section of the text (www.pathoma.com).
We recommend that students use Fundamentals of Pathology during their medical
courses, taking notes in the margin as pertinent topics are covered. When exam time
comes around, these notes will likely be invaluable.
For examination preparation, we suggest students read the material first, then listen to
the online lecture, and then reread the material to develop a solid grasp of each topic. One
should not become disheartened if they are not able to retain all the information
contained herein. This deceptively slim volume covers a tremendous amount of material,
and repetition will be a key aid as you progress in your studies.
An effort has been made to emphasize concepts and principles over random facts,
the forest rather than the trees. Attention to the same by the student will provide a deeper,
more meaningful understanding of human disease. We must always remind ourselves that
ultimately our goal is to learn, to share, and to serve. Fundamentals of Pathology was
developed with this goal in mind.
Husain A. Sattar, MD
Chicago, Illinois

ACKNOWLEDGMENTS
This work would not have been possible without the support and encouragement of those
around me. To begin with, I would like to acknowledge Shaykh Zulfiqar Ahmad, whose clear
vision has guided me to horizons I would never have known. My family is to be acknowledged
for their limitless sacrifice, in particular the constant encouragement and support of my wife
Amina, who has proved through the years to be the wind under my wings. Thomas Krausz,
MD and Ali ya Husain, MD (both Professors of Pathology at the University of Chicago) deserve
particular mention for their valuable advice and guiding vision, both in the development of
this book as well as my career. Special thanks to the multiple reviewers at medical centers
throughout the country for their critical comments, in particular Mir Basharath Alikhan, MD
(Pathology resident, University of Chicago) and Joshua T.B. Williams (Class of 2013, Pritzker
School of Medicine, University of Chicago) for their extensive review. Olaf Nelson (Chinook
Design, Inc.) is to be commended for his excellent layout and design. Finally, I would be remiss
without acknowledging my students, who give meaning to what I do.
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TO MY PARENTS AND EACH OF MY TEACHERS - YOUR SACRIFICE
FORMS THE FOUNDATION UPON WHICH OUR WORK IS BUILT
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Growth
GrowthAdaptations,
Adaptations,Cellular
Cellular
Injury,
Injury,and CellDeath
andCell Death 11

GROWTH ADAPTATIONS
I. BASIC PRINCIPLES
A. An organ is in homeostasis with the physiologic stress placed on it.
B. An increase, decrease, or change in stress on an organ can result in growth
adaptations.

IL HYPERPLASIA AND HYPERTROPHY
A. An increase in stress leads to an increase in organ size.
1. Occurs via an increase in the size (hypertrophy) and/or the number
(hyperplasia) of cells
B. Hypertrophy involves gene activation, protein synthesis, and production of
organelles.
C. Hyperplasia involves the production of new cells from stem cells.
D. Hyperplasia and hypertrophy generally occur together (e.g., uterus during
pregnancy).
1. Permanent tissues (e.g., cardiac muscle, skeletal muscle, and nerve), however,
cannot make new cells and undergo hypertrophy only.
2. For example, cardiac myocytes undergo hypertrophy, not hyperplasia, in
response to systemic hypertension (Fig. 1.1).
E. Pathologic hyperplasia (e.g., endometrial hyperplasia) can progress to dysplasia and,
eventually, cancer.
1. A notable exception is benign prostatic hyperplasia (BPH), which does not
increase the risk for prostate cancer.

III. ATROPHY
A. A decrease in stress (e.g., decreased hormonal stimulation, disuse, or decreased
nutrients/blood supply) leads to a decrease in organ size (atrophy).
1. Occurs via a decrease in the size and number of cells
B. Decrease in cell number occurs via apoptosis.
C. Decrease in cell size occurs via ubiquitin-proteosome degradation of the
cytoskeleton and autophagy of cellular components.
1. In ubiquitin-proteosome degradation, intermediate filaments of the cytoskeleton
are "tagged" with ubiquitin and destroyed by proteosomes.
2. Autophagy of cellular components involves generation of autophagic vacuoles.
These vacuoles fuse with lysosomes whose hydrolytic enzymes breakdown
cellular components.

IV. METAPLASIA
A. A change in stress on an organ leads to a change in cell type (metaplasia).
1. Most commonly involves change of one type of surface epithelium (squamous,
columnar, or urothelial) to another
2. Metaplastic cells are better able to handle the new stress.
B. Barrett esophagus is a classic example.

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2 FUNDAMENTALS OF PATHOLOGY

1. Esophagus is normally lined by nonkeratinizing squamous epithelium (suited to
handle friction of a food bolus).
2. Acid reflux from the stomach causes metaplasia to nonciliated, mucin-producing
columnar cells (better able to handle the stress of acid, Fig. 1.2).
C. Metaplasia occurs via reprogramming of stem cells, which then produce the new cell
type.
1. Metaplasia is reversible, in theory, with removal of the driving stressor.
2. For example, treatment of gastroesophageal reflux may reverse Barrett
esophagus.
D. Under persistent stress, metaplasia can progress to dysplasia and eventually result in
cancer.
1. For example, Barrett esophagus may progress to adenocarcinoma of the
esophagus.
2. A notable exception is apocrine metaplasia of breast, which carries no increased
risk for cancer.
E. Vitamin A deficiency can also result in metaplasia.
1. Vitamin A is necessary for differentiation of specialized epithelial surfaces such
as the conjunctiva covering the eye.
2. In vitamin A deficiency, the thin squamous lining of the conjunctiva undergoes
metaplasia into stratified keratinizing squamous epithelium. This change is
called keratomalacia (Fig. 1.3).
F. Mesenchymal (connective) tissues can also undergo metaplasia.
1. A classic example is myositis ossificans in which connective tissue within muscle
changes to bone during healing after trauma (Fig. 1.4).

V. DYSPLASIA
A. Disordered cellular growth
B. Most often refers to proliferation of precancerous cells
1. For example, cervical intraepithelial neoplasia (CIN) represents dysplasia and is
a precursor to cervical cancer.
C. Often arises from longstanding pathologic hyperplasia (e.g., endometrial
hyperplasia) or metaplasia (e.g., Barrett esophagus)
D. Dysplasia is reversible, in theory, with alleviation of inciting stress.
1. If stress persists, dysplasia progresses to carcinoma (irreversible).

VI. APLASIA AND HYPOPLASIA
A. Aplasia is failure of cell production during embryogenesis (e.g., unilateral renal
agenesis).
B. Hypoplasia is a decrease in cell production during embryogenesis, resulting in a
relatively small organ (e.g., streak ovary in Turner syndrome).

Fig. 1.1 Left ventricular hypertrophy. (Courtesy of Fig.1.2 Barrett esophagus.
Aliya Husain, MD)
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Growth Adaptations, Cellular Injury, and Cell Death 3

CELLULAR INJURY
I. BASIC PRINCIPLES
A. Cellular injury occurs when a stress exceeds the cell's ability to adapt.
B. The likelihood of injury depends on the type of stress, its severity, and the type of cell
affected.
1. Neurons are highly susceptible to ischemic injury; whereas, skeletal muscle is
relatively more resistant.
2. Slowly developing ischemia (e.g., renal artery atherosclerosis) results in atrophy;
whereas, acute ischemia (e.g., renal artery embolus) results in injury.
C. Common causes of cellular injury include inflammation, nutritional deficiency or
excess, hypoxia, trauma, and genetic mutations.

II. HYPOXIA
A. Low oxygen delivery to tissue; important cause of cellular injury
1. Oxygen is the final electron acceptor in the electron transport chain of oxidative
phosphorylation.
2. Decreased oxygen impairs oxidative phosphorylation, resulting in decreased ATP
production.
3. Lack of ATP (essential energy source) leads to cellular injury.
B. Causes of hypoxia include ischemia, hypoxemia, and decreased O2-carrying capacity
of blood.
C. Ischemia is decreased blood flow through an organ. Arises with
1. Decreased arterial perfusion (e.g., atherosclerosis)
2. Decreased venous drainage (e.g., Budd-Chiari syndrome)
3. Shock - generalized hypotension resulting in poor tissue perfusion
D. Hypoxemia is a low partial pressure of oxygen in the blood (Pao2 < 60 mm Hg, Sao2 <
90%). Arises with
1. High altitude - Decreased barometric pressure results in decreased PAo2
2. Hypoventilation - Increased PAco2 results in decreased PAo2
3. Diffusion defect - PAo2 not able to push as much O2 into the blood due to a
thicker
diffusion barrier (e.g., interstitial pulmonary fibrosis)
4. V/Q mismatch - Blood bypasses oxygenated lung (circulation problem, e.g., right-
to-left shunt), or oxygenated air cannot reach blood (ventilation problem,
e.g., atelectasis).
E. Decreased O2-carrying capacity arises with hemoglobin (Hb) loss or dysfunction.
Examples include
1. Anemia (decrease in RBC mass)-Pao2 normal; Sao2 normal
2. Carbon monoxide poisoning

Fig. 1.3 Keratomalacia. (Courtesy of Fig.1.4 Myositis Ossificans. (Reprinted with
motherchildnutrition.org) permission from orthopaedia.com)
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4 FUNDAMENTALS OF PATHOLOGY

i. CO binds hemoglobin more avidly than oxygen-Pao2 normal; Sao2
decreased
ii. Exposures include smoke from fires and exhaust from cars or gas heaters.
iii. Classic finding is cherry-red appearance of skin.
iv. Early sign of exposure is headache; significant exposure leads to coma and
death.
3. Methemoglobinemia
i. Iron in heme is oxidized to Fe3+, which cannot bind oxygen-Pao2 normal;
Sao2 decreased
ii. Seen with oxidant stress (e.g., sulfa and nitrate drugs) or in newborns
iii. Classic finding is cyanosis with chocolate-colored blood.
iv. Treatment is intravenous methylene blue, which helps reduce Fe2+ back to
Fe2+state.

III. REVERSIBLE AND IRREVERSIBLE CELLULAR INJURY
A. Hypoxia impairs oxidative phosphorylation resulting in decreased ATP.
B. Low ATP disrupts key cellular functions including
1. Na+-K+pump, resulting in sodium and water buildup in the cell
2. Ca 2+pump, resulting in Ca2+ buildup in the cytosol of the cell
3. Aerobic glycolysis, resulting in a switch to anaerobic glycolysis. Lactic acid
buildup results in low pH, which denatures proteins and precipitates DNA.
C. The initial phase of injury is reversible. The hallmark of reversible injury is cellular
swelling.
1. Cytosol swelling results in loss of microvilli and membrane blebbing.
2. Swelling of the rough endoplasmic reticulum (RER) results in dissociation of
ribosomes and decreased protein synthesis.
D. Eventually, the damage becomes irreversible. The hallmark of irreversible injury is
membrane damage.
1. Plasma membrane damage results in
i. Cytosolic enzymes leaking into the serum (e.g., cardiac troponin)
ii. Additional calcium entering into the cell
2. Mitochondrial membrane damage results in
i. Loss of the electron transport chain (inner mitochondrial membrane)
ii. Cytochrome c leaking into cytosol (activates apoptosis)
3. Lysosome membrane damage results in hydrolytic enzymes leaking into the
cytosol, which, in turn, are activated by the high intracellular calcium.
E. The end result of irreversible injury is cell death.

Fig. 1.5 Coagulative necrosis of kidney. A, Gross appearance. B, Microscopic appearance. C, Normal kidney histology for comparison.
(A, Courtesy of Aliya Husain, MD)
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Growth Adaptations, Cellular Injury, and Cell Death 5

CELL DEATH
I. BASIC PRINCIPLES
A. The morphologic hallmark of cell death is loss of the nucleus, which occurs via
nuclear condensation (pyknosis), fragmentation (karyorrhexis), and dissolution
(karyolysis).
B. The two mechanisms of cell death are necrosis and apoptosis.

II. NECROSIS
A. Death of large groups of cells followed by acute inflammation
B. Due to some underlying pathologic process; never physiologic
C. Divided into several types based on gross features

III. GROSS PATTERNS OF NECROSIS
A. Coagulative necrosis
1. Necrotic tissue that remains firm (Fig. 1.5A); cell shape and organ structure are
preserved by coagulation of proteins, but the nucleus disappears (Fig. 1.5B).
2. Characteristic of ischemic infarction of any organ except the brain
3. Area of infarcted tissue is often wedge-shaped (pointing to focus of vascular
occlusion) and pale.
4. Red infarction arises if blood re-enters a loosely organized tissue (e.g., pulmonary
or testicular infarction, Fig. 1.6).
B. Liquefactive necrosis
1. Necrotic tissue that becomes liquefied; enzymatic lysis of cells and protein results
in liquefaction.
2. Characteristic of
i. Brain infarction - Proteolytic enzymes from microglial cells liquefy the
brain.
ii. Abscess - Proteolytic enzymes from neutrophils liquefy tissue.
iii. Pancreatitis - Proteolytic enzymes from pancreas liquefy parenchyma.
C. Gangrenous necrosis
1. Coagulative necrosis that resembles mummified tissue (dry gangrene, Fig. 1.7)
2. Characteristic of ischemia of lower limb and GI tract
3. If superimposed infection of dead tissues occurs, then liquefactive necrosis ensues
(wet gangrene).
D. Caseous necrosis
1. Soft and friable necrotic tissue with "cottage cheese-like" appearance (Fig. 1.8)
2. Combination of coagulative and liquefactive necrosis
3. Characteristic of granulomatous inflammation due to tuberculous or fungal
infection

Fig. 1.6 Hemorrhagic infarction of testicle. Fig. 1.7 Dry gangrene. Fig. 1.8 Caseous necrosis of lung. (Courtesy ofYale
(Courtesy of humpath.com) Rosen, MD)
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6 FUNDAMENTALS OF PATHOLOGY

E. Fat necrosis
1. Necrotic adipose tissue with chalky-white appearance due to deposition of
calcium (Fig. 1.9)
2. Characteristic of trauma to fat (e.g., breast) and pancreatitis-mediated damage of
peripancreatic fat
3. Fatty acids released by trauma (e.g., to breast) or lipase (e.g., pancreatitis) join
with calcium via a process called saponification.
i. Saponification is an example of dystrophic calcification in which calcium
deposits on dead tissues. In dystrophic calcification, the necrotic tissue
acts as a nidus for calcification in the setting of normal serum calcium and
phosphate.
ii. Metastatic calcification, as opposed to dystrophic calcification, occurs when
high serum calcium or phosphate levels lead to calcium deposition in normal
tissues (e.g., hyperparathyroidism leading to nephrocalcinosis).
F. Fibrinoid necrosis
1. Necrotic damage to blood vessel wall
2. Leaking of proteins (including fibrin) into vessel wall results in bright pink
staining of the wall microscopically (Fig. 1.10).
3. Characteristic of malignant hypertension and vasculitis

IV.APOPTOSIS
A. Energy (ATP)-dependent, genetically programmed cell death involving single cells or
small groups of cells. Examples include
1. Endometrial shedding during menstrual cycle
2. Removal of cells during embryogenesis
3. CD8 + T cell-mediated killing of virally infected cells
B. Morphology
1. Dying cell shrinks, leading cytoplasm to become more eosinophilic (pink, Fig. l.ll).
2. Nucleus condenses and fragments in an organized manner.
3. Apoptotic bodies fall from the cell and are removed by macrophages; apoptosis is
not followed by inflammation.
C. Apoptosis is mediated by caspases that activate proteases and endonucleases.
1. Proteases break down the cytoskeleton.
2. Endonucleases break down DNA.
D. Caspases are activated by multiple pathways.
1. Intrinsic mitochondrial pathway
i. Cellular injury, DNA damage, or decreased hormonal stimulation leads to
inactivation of Bcl2.
ii. Lack of Bcl2 allows cytochrome c to leak from the inner mitochondrial matrix
into the cytoplasm and activate caspases.

Fig. 1.9 Fat necrosis of peri-pancreatic adipose Fig. 1.10 Fibrinoid necrosis of vessel. Fig.1.11 Apoptosis.
tissue. (Courtesy of humpath.com)
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Growth Adaptations, Cellular Injury, and Cell Death 7

2. Extrinsic receptor-ligand pathway
i. FAS ligand binds FAS death receptor (CD95) on the target cell, activating
caspases (e.g., negative selection of thymocytes in thymus).
ii. Tumor necrosis factor (TNF) binds TNF receptor on the target cell,
activating caspases.
3. Cytotoxic CD8+ T cell-mediated pathway
i. Perforins secreted by CD8 + T cell create pores in membrane of target cell.
ii. Granzyme from CD8 + T cell enters pores and activates caspases.
iii. CD8 + T-cell killing of virally infected cells is an example.

FREE RADICAL INJURY
I. BASIC PRINCIPLES
A. Free radicals are chemical species with an unpaired electron in their outer orbit.
B. Physiologic generation of free radicals occurs during oxidative phosphorylation.
1. Cytochrome c oxidase (complex IV) transfers electrons to oxygen.
2. Partial reduction of O2 yields superoxide (O2ꜙ), hydrogen peroxide (H2O2 ), and
hydroxyl radicals (˙OH ).
C. Pathologic generation of free radicals arises with
1. Ionizing radiation - water hydrolyzed to hydroxyl free radical
2. Inflammation - NADPH oxidase generates superoxide ions during oxygen-
dependent killing by neutrophils.
3. Metals (e.g., copper and iron)-Fe 2+ generates hydroxyl free radicals (Fenton
reaction).
4. Drugs and chemicals - P450 system of liver metabolizes drugs (e.g.,
acetaminophen), generating free radicals.
D. Free radicals cause cellular injury via peroxidation of lipids and oxidation of DNA
and proteins; DNA damage is implicated in aging and oncogenesis.
E. Elimination of free radicals occurs via multiple mechanisms.
1. Antioxidants (e.g., glutathione and vitamins A , C, and E)
2. Enzymes
I) Superoxide dismutase (in mitochondria) - Superoxide (O2ꜙ) → H2O2
II) Glutathione peroxidase (in mitochondria) - 2GSH + free radical → GS-SG
and H2O
III) Catalase (in peroxisomes) - H 2O2 → O2ꜙ and H2O
3. Metal carrier proteins (e.g., transferrin and ceruloplasmin)

II. EXAMPLES OF FREE RADICAL INJURY
A. Carbon tetrachloride (CCl4)
1. Organic solvent used in the dry cleaning industry
2. Converted to CCl3 free radical by P450 system of hepatocytes
3. Results in cell injury with swelling of RER; consequently, ribosomes detach,
impairing protein synthesis.
4. Decreased apolipoproteins lead to fatty change in the liver (Fig. 1.12).
B. Reperfusion injury
1. Return of blood to ischemic tissue results in production of O2 -derived free
radicals, which further damage tissue.
2. Leads to a continued rise in cardiac enzymes (e.g., troponin) after reperfusion of
infarcted myocardial tissue
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IK * *

8 FUNDAMENTALS OF PATHOLOGY

AMYLOIDOSIS
I. BASIC PRINCIPLES
A. Amyloid is a misfolded protein that deposits in the extracellular space, thereby
damaging tissues.
B. Multiple proteins can deposit as amyloid. Shared features include
1. β- pleated sheet configuration
2. Congo red staining and apple-green birefringence when viewed microscopically
under polarized light (Fig. 1.13)
C. Deposition can be systemic or localized.

II. SYSTEMIC AMYLOIDOSIS
A. Amyloid deposition in multiple organs; divided into primary and secondary
amyloidosis
B. Primary amyloidosis is systemic deposition of AL amyloid, which is derived from
immunoglobulin light chain.
1. Associated with plasma cell dyscrasias (e.g., multiple myeloma)
C. Secondary amyloidosis is systemic deposition of AA amyloid, which is derived from
serum amyloid-associated protein (SAA).
1. SAA is an acute phase reactant that is increased in chronic inflammatory states,
malignancy, and Familial Mediterranean fever (FMF).
2. FMF is due to a dysfunction of neutrophils (autosomal recessive) and occurs in
persons of Mediterranean origin.
i. Presents with episodes of fever and acute serosal inflammation (can mimic
appendicitis, arthritis, or myocardial infarction)
ii. High SAA during attacks deposits as AA amyloid in tissues.
D. Clinical findings of systemic amyloidosis are diverse since almost any tissue can be
involved. Classic findings include
1. Nephrotic syndrome; kidney is the most common organ involved.
2. Restrictive cardiomyopathy or arrhythmia
3. Tongue enlargement, malabsorption, and hepatosplenomegaly
E. Diagnosis requires tissue biopsy. Abdominal fat pad and rectum are easily accessible
biopsy targets.
F. Damaged organs must be transplanted. Amyloid cannot be removed.

III. LOCALIZED AMYLOIDOSIS
A. Amyloid deposition usually localized to a single organ.
B. Senile cardiac amyloidosis
1. Non-mutated serum transthyretin deposits in the heart.
2. Usually asymptomatic; present in 25% of individuals > 80 years of age
C. Familial amyloid cardiomyopathy

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Fig.1.12 Fatty change of liver. Fig. 1.13 Amyloid. A, Congo red. B, Apple-green birefringence. (Courtesy of Ed Uthman, MD)
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Growth Adaptations, Cellular Injury, and Cell Death 9

1. Mutated serum transthyretin deposits in the heart leading to
restrictive cardiomyopathy.
2. 5% of African Americans carry the mutated gene.
D. Non-insulin-dependent diabetes mellitus (type II)
1. Amylin (derived from insulin) deposits in the islets of the pancreas.
E. Alzheimer disease
1. Aβ amyloid (derived from β-amyloid precursor protein) deposits in the brain
forming amyloid plaques.
2. Gene for β-APP is present on chromosome 21. Most individuals with Down
syndrome (trisomy 21) develop Alzheimer disease by the age of 40 (early-onset).
F. Dialysis-associated amyloidosis
1. β2-microglobulin deposits in joints.
G. Medullary carcinoma of the thyroid
1. Calcitonin (produced by tumor cells) deposits within the tumor ('tumor cells in
an amyloid background').

I
REMINDER

Thank you for choosing Pathoma for your studies. We strive to provide the highest quality educational materials while
keeping affordability in mind. A tremendous amount of time and effort has gone into developing these materials, so we
appreciate your legitimate use of this program. It speaks to your integrity as a future physician and the high ethical
standards that we all set forth for ourselves when taking the Hippocratic oath. Unauthorized use of Patho ma materials is
contrary to the ethical standards of a training physician and is a violation of copyright. Pathoma videos are updated on a
regular basis and the most current version, as well as a complete list of errata, can be accessed through your account at
Pathoma.com.
Sincerely,
Dr. Sattar, MD
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Inflammation,
Inflammatory Disorders, 1
and Wound Healing

INTRODUCTION
I. INFLAMMATION
A. Allows inflammatory cells, plasma proteins (e.g., complement), and fluid to exit
blood vessels and enter the interstitial space
B. Divided into acute and chronic inflammation

ACUTE INFLAMMATION
I. BASIC PRINCIPLES
A. Characterized by the presence of edema and neutrophils in tissue (Fig. 2.lA)
B. Arises in response to infection (to eliminate pathogen) or tissue necrosis (to clear
necrotic debris)
C. Immediate response with limited specificity (innate immunity)

IL MEDIATORS OF ACUTE INFLAMMATION
A. Toll-like receptors (TLRs)
1. Present on cells of the innate immune system (e.g., macrophages and dendritic
cells)
2. Activated by pathogen-associated molecular patterns (PAMPs) that are
commonly shared by microbes
i. CD14 (a co-receptor for TLR4) on macrophages recognizes lipopoly-
saccharide (a PAMP) on the outer membrane of gram-negative bacteria.
3. TLR activation results in upregulation of NF-κB, a nuclear transcription factor
that activates immune response genes leading toproduction of multiple immune
mediators.
4. TLRs are also present on cells of adaptive immunity (e.g., lymphocytes) and,
hence, play an important role in mediating chronic inflammation.
B. Arachidonic acid (AA) metabolites
1. AA is released from the phospholipid cell membrane by phospholipase A2 and
then acted upon by cyclooxygenase or 5-lipoxygenase.
i. Cyclooxygenase produces prostaglandins (PG).
a. PGI 2, PGD 2, and PGE2 mediate vasodilation and increased vascular
permeability.
b. PGE2 also mediates pain and fever.
ii. 5-lipoxygenase produces leukotrienes (LT).
a. LTB 4 attracts and activates neutrophils.
b. LTC 4, LTD 4, and LTE 4 (slow reacting substances of anaphylaxis) mediate
vasoconstriction, bronchospasm, and increased vascular permeability.
C. Mast cells
1. Widely distributed throughout connective tissue
2. Activated by (1) tissue trauma, (2) complement proteins C3a and C5a, or (3)
cross-linking of cell-surface IgE by antigen

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12 FUNDAMENTALS OF PATHOLOGY

Immediate response involves release of preformed histamine granules, which
i.
mediate vasodilation of arterioles and increased vascular permeability.
ii. Delayed response involves production of arachidonic acid metabolites,
particularly leukotrienes.
D. Complement
1. Proinflammatory serum proteins that "complement" inflammation
2. Circulate as inactive precursors; activation occurs via
i. Classical pathway - C1 binds IgG or IgM that is bound to antigen.
ii. Alternative pathway - Microbial products directly activate complement.
iii. Mannose-binding lectin (MBL) pathway - MBL binds to mannose on
microorganisms and activates complement.
3. All pathways result in production of C3 convertase (mediates C3 →C3a and
C3b), which, in turn, produces C5 convertase (mediates C5 → C5a and C5b).
C5b complexes with C6-C9 to form the membrane attack complex (MAC).
i. C3a and C5a (anaphylatoxins) - trigger mast cell degranulation, resulting in
histamine-mediated vasodilation and increased vascular permeability
ii. C5a - chemotactic for neutrophils
iii. C3b - opsonin for phagocytosis
iv. MAC - lyses microbes by creating a hole in the cell membrane
E. Hageman factor (Factor XII)
1. Inactive proinflammatory protein produced in liver
2. Activated upon exposure to subendothelial or tissue collagen; in turn, activates
i. Coagulation and fibrinolytic systems
ii. Complement
iii. Kinin system - Kinin cleaves high-molecular-weight kininogen (HMWK) to
bradykinin, which mediates vasodilation and increased vascular
permeability (similar to histamine), as well as pain.

III. CARDINAL SIGNS OF INFLAMMATION
A. Redness (rubor) and warmth (calor)
1. Due to vasodilation, which results in increased blood flow
2. Occurs via relaxation of arteriolar smooth muscle; key mediators are histamine,
prostaglandins, and bradykinin.
B. Swelling (tumor)
1. Due to leakage of fluid from postcapillary venules into the interstitial space
(exudate)
2. Key mediators are (1) histamine, which causes endothelial cell contraction and
(2) tissue damage, resulting in endothelial cell disruption.
C. Pain (dolor)
1. Bradykinin and PGE2 sensitize sensory nerve endings.

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with lymphocytes and plasma cells.
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Inflammation, Inflammatory Disorders, and Wound Healing 13

D. Fever
1. Pyrogens (e.g., LPS from bacteria) cause macrophages to release IL-1
and TNF, which increase cyclooxygenase activity in perivascular cells of
the hypothalamus.
2. Increased PGE2 raises temperature set point.

IV. NEUTROPHIL ARRIVAL AND FUNCTION
A. Step 1 - Margination
1. Vasodilation slows blood flow in postcapillary venules.
2. Cells marginate from center of flow to the periphery.
B. Step 2 - Rolling
1. Selectin "speed bumps" are upregulated on endothelial cells.
i. P-selectin release from Weibel-Palade bodies is mediated by histamine.
ii. E-selectin is induced by TNF and IL-1.
2. Selectins bind sialyl Lewis X on leukocytes.
3. Interaction results in rolling of leukocytes along vessel wall.
C. Step 3 - Adhesion
1. Cellular adhesion molecules (ICAM and VCAM) are upregulated on
endothelium by TNF and IL-1.
2. Integrins are upregulated on leukocytes by C5a and LTB4
3. Interaction between CAMs and integrins results in firm adhesion of leukocytes to
the vessel wall.
4. Leukocyte adhesion deficiency is most commonly due to an autosomal recessive
defect of integrins (CD18 subunit).
i. Clinical features include delayed separation of the umbilical cord, increased
circulating neutrophils (due to impaired adhesion of marginated pool of
leukocytes), and recurrent bacterial infections that lack pus formation.
D. Step 4 - Transmigration and Chemotaxis
1. Leukocytes transmigrate across the endothelium of postcapillary venules and
move toward chemical attractants (chemotaxis).
2. Neutrophils are attracted by bacterial products, IL-8, C5a, and LTB4.
E. Step 5 - Phagocytosis
1. Consumption of pathogens or necrotic tissue; phagocytosis is enhanced by
opsonins (IgG and C3b).
2. Pseudopods extend from leukocytes to form phagosomes, which are internalized
and merge with lysosomes to produce phagolysosomes.
3. Chediak-Higashi syndrome is a protein trafficking defect (autosomal recessive)
characterized by impaired phagolysosome formation. Clinical features include
i. Increased risk of pyogenic infections
ii. Neutropenia (due to intramedullary death of neutrophils)
iii. Giant granules in leukocytes (due to fusion of granules arising from the Golgi
apparatus)
iv. Defective primary hemostasis (due to abnormal dense granules in platelets)
v. Albinism
vi. Peripheral neuropathy
F. Step 6 - Destruction of phagocytosed material
1. O2-dependent killing is the most effective mechanism.
2. HOCl generated by oxidative burst in phagolysosomes destroys phagocytosed
microbes.
i. O2 is converted to O 2 ꜙ by NADPH oxidase (oxidative burst).
ii. O2ꜙ is converted to H2O2 by superoxide dismutase (SOD).
iii. H2O2 is converted to HOCl (bleach) by myeloperoxidase (MPO).
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14 FUNDAMENTALS OF PATHOLOGY
«

3. Chronic granulomatous disease (CGD) is characterized by poor O2-dependent
killing.
i. Due to NADPH oxidase defect (X-linked or autosomal recessive)
ii. Leads to recurrent infection and granuloma formation with catalase-positive
organisms, particularly Staphylococcus aureus, Pseudomonas cepacia,
Serratia marcescens, Nocardia, and Aspergillus
iii. Nitroblue tetrazolium test is used to screen for CGD. Leukocytes are
incubated with NBT dye, which turns blue if NADPH oxidase can convert
O2 to O2ꜙ, but remains colorless if NADPH oxidase is defective.
4. MPO deficiency results in defective conversion of H2O2 to HOCl.
i. Increased risk for Candida infections; however, most patients are
asymptomatic.
ii. NBT is normal; respiratory burst (O2 to H2O2) is intact.
5. O2-independent killing is less effective than O2 -dependent killing and occurs via
enzymes present in leukocyte secondary granules (e.g., lysozyme in macrophages
and major basic protein in eosinophils).
G. Step 7 - Resolution
1. Neutrophils undergo apoptosis and disappear within 24 hours after resolution of
the inflammatory stimulus.

V. MACROPHAGES
A. Macrophages predominate after neutrophils and peak 2-3 days after inflammation
begins.
1. Derived from monocytes in blood
B. Arrive in tissue via the margination, rolling, adhesion, and transmigration sequence
C. Ingest organisms via phagocytosis (augmented by opsonins) and destroy
phagocytosed material using enzymes (e.g., lysozyme) in secondary granules (O 2-
independent killing)
D. Manage the next step of the inflammatory process. Outcomes include
1. Resolution and healing - Anti-inflammatory cytokines (e.g., IL-10 and TGF-
β) are produced by macrophages.
2. Continued acute inflammation - marked by persistent pus formation; IL-8
from macrophages recruits additional neutrophils.
3. Abscess - acute inflammation surrounded by fibrosis; macrophages mediate
fibrosis via fibrogenic growth factors and cytokines.
4. Chronic inflammation - Macrophages present antigen to activate CD4+
helper T cells, which secrete cytokines that promote chronic inflammation.

CHRONIC INFLAMMATION
I. BASIC PRINCIPLES
A. Characterized by the presence of lymphocytes and plasma cells in tissue (Fig. 2.lB)
B. Delayed response, but more specific (adaptive immunity) than acute inflammation
C. Stimuli include (1) persistent infection (most common cause); (2) infection with
viruses, mycobacteria, parasites, and fungi; (3) autoimmune disease; (4) foreign
material; and (5) some cancers.

II. T LYMPHOCYTES
A. Produced in bone marrow as progenitor T cells
B. Further develop in the thymus where the T-cell receptor (TCR) undergoes
rearrangement and progenitor cells become CD4 + helper T cells or CD8 + cytotoxic T
cells
1. T cells use TCR complex (TCR and CD3) for antigen surveillance.
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Inflammation, Inflammatory Disorders, and Wound Healing 15

2. TCR complex recognizes antigen presented on MHC molecules.
i. CD4+ T cells - MHC class II
ii. CD8+ T cells - MHC class I
3. Activation of T cells requires (1) binding of antigen/MHC complex and (2)
an additional 2nd signal.
C. CD4 + helper T-cell activation
1. Extracellular antigen (e.g., foreign protein) is phagocytosed, processed, and
presented on MHC class II, which is expressed by antigen presenting cells
(APCs).
2. B7 on APC binds CD28 on CD4 + helper T cells providing 2nd activation signal.
3. Activated CD4 + helper T cells secrete cytokines that "help" inflammation and are
divided into two subsets.
i. TH1 subset secretes IFN-γ (activates macrophage, promotes B-cell class
switching from IgM to IgG, promotes TH1phenotype and inhibits TH2
phenotype).
ii. T H 2 subset secretes IL-4 (facilitates B-cell class switching to IgE), IL-5
(eosinophil chemotaxis and activation, and class switching to IgA), and IL-13
(function similar to IL-4).
D. CD8 + cytotoxic T-cell activation
1. Intracellular antigen (derived from proteins in the cytoplasm) is processed and
presented on MHC class I, which is expressed by all nucleated cells and platelets.
2. IL-2 from CD4 + TH1 cell provides 2nd activation signal.
3. Cytotoxic T cells are activated for killing.
4. Killing occurs via
i. Secretion of perforin and granzyme; perforin creates pores that allow
granzyme to enter the target cell, activating apoptosis.
ii. Expression of FasL, which binds Fas on target cells, activating apoptosis

III. B LYMPHOCYTES
A. Immature B cells are produced in the bone marrow and undergo immunoglobulin
rearrangements to become naïve B cells that express surface IgM and IgD.
B. B-cell activation occurs via
1. Antigen binding by surface IgM or IgD; results in maturation to IgM- or IgD-
secreting plasma cells
2. B-cell antigen presentation to CD4+ helper T cells via MHC class IL
i. CD40 receptor on B cell binds CD40L on helper T cell, providing 2nd
activation signal.
ii. Helper T cell then secretes IL-4 and IL-5 (mediate B-cell isotype switching,
hypermutation, and maturation to plasma cells).

IV. GRANULOMATOUS INFLAMMATION
A. Subtype of chronic inflammation
B. Characterized by granuloma, which is a collection of epithelioid histiocytes
(macrophages with abundant pink cytoplasm), usually surrounded by giant cells and
a rim of lymphocytes
C. Divided into noncaseating and caseating subtypes
1. Noncaseating granulomas lack central necrosis (Fig. 2.2A). Common etiologies
include reaction to foreign material, sarcoidosis, beryllium exposure, Crohn
disease, and cat scratch disease.
2. Caseating granulomas exhibit central necrosis and are characteristic of
tuberculosis and fungal infections (Fig. 2.2B).
D. Steps involved in granuloma formation
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FUNDAMENTALS * /
OF PATHOLOGY

1. Macrophages process and present antigen via MHC class II to CD4 + helper T
cells.
2. Interaction leads macrophages to secrete IL-12, inducing CD4 + helper T cells to
differentiate into T H1 subtype.
3. TH1cells secrete IFN-γ, which converts macrophages to epithelioid histiocytes
and giant cells.

PRIMARY IMMUNODEFICIENCY
I. DIGEORGE SYNDROME
A. Developmental failure of the third and fourth pharyngeal pouches
1. Due to 22q11 microdeletion
B. Presents with T-cell deficiency (lack of thymus); hypocalcemia (lack of parathyroids);
and abnormalities of heart, great vessels, and face

II. SEVERE COMBINED IMMUNODEFICIENCY (SCID)
A. Defective cell-mediated and humoral immunity
B. Etiologies include
1. Cytokine receptor defects - Cytokine signaling is necessary for proliferation
and maturation of B and T cells.
2. Adenosine deaminase (ADA) deficiency - ADA is necessary to deaminate
adenosine and deoxyadenosine for excretion as waste products; buildup of
adenosine and deoxyadenosine is toxic to lymphocytes.
3. MHC class II deficiency - MHC class II is necessary for CD4 + helper T cell
activation and cytokine production.
C. Characterized by susceptibility to fungal, viral, bacterial, and protozoal infections,
including opportunistic infections and live vaccines
D. Treatment is sterile isolation ('bubble baby') and stem cell transplantation.

Ill. X-LINKED AGAMMAGLOBULINEMIA
A. Complete lack of immunoglobulin due to disordered B-cell maturation
1. Pre- and pro-B cells cannot mature.
B. Due to mutated Bruton tyrosine kinase; X-linked
C. Presents after 6 months of life with recurrent bacterial, enterovirus (e.g., polio and
coxsackievirus), and Giardia lamblia infections; maternal antibodies present during
the first 6 months of life are protective.
D. Live vaccines (e.g., polio) must be avoided.

IV. COMMON VARIABLE IMMUNODEFICIENCY (CVID)
A. Low immunoglobulin due to B-cell or helper T-cell defects

Fig. 2.2 Granuloma. A, Noncaseating. B, Caseating. Fig. 2.3 Angioedema. (Courtesy of James
Heilman, MD, Wikipedia)
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Inflammation, Inflammatory Disorders, and Wound Healing 17

B. Increased risk for bacterial, enterovirus, and Giardia lamblia infections, usually in
late childhood
C. Increased risk for autoimmune disease and lymphoma

V. IgA DEFICIENCY
A. Low serum and mucosal IgA; most common immunoglobulin deficiency
B. Increased risk for mucosal infection, especially viral; however, most patients are
asymptomatic.

VI. HYPER-IgM SYNDROME
A. Characterized by elevated IgM
B. Due to mutated CD40L (on helper T cells) or CD40 receptor (on B cells)
1. Second signal cannot be delivered to helper T cells during B-cell activation.
2. Consequently, cytokines necessary for immunoglobulin class switching are not
produced.
C. Low IgA, IgG, and IgE result in recurrent pyogenic infections (due to poor
opsonization), especially at mucosal sites.

VII. WISKOTT-ALDRICH SYNDROME
A. Characterized by thrombocytopenia, eczema, and recurrent infections (defective
humoral and cellular immunity); bleeding is a major cause of death
B. Due to mutation in the WASP gene; X-linked

VIII. COMPLEMENT DEFICIENCIES
A. C5-C9 deficiencies-increased risk for Neisseria infection (N gonorrhoeae and N
meningitidis)
B. Cl inhibitor deficiency-results in hereditary angioedema, which is characterized by
edema of the skin (especially periorbital, Fig. 2.3) and mucosal surfaces

AUTOIMMUNE DISORDERS
I. BASIC PRINCIPLES
A. Characterized by immune-mediated damage of self tissues
1. US prevalence is 1%-2%.
B. Involves loss of self-tolerance
1. Self-reactive lymphocytes are regularly generated but develop central (thymus
and bone marrow) or peripheral tolerance.
2. Central tolerance in thymus leads to T-cell (thymocyte) apoptosis or generation
of regulatory T cells.
i. AIRE mutations result in autoimmune polyendocrine syndrome.
3. Central tolerance in bone marrow leads to receptor editing or B-cell apoptosis.
4. Peripheral tolerance leads to anergy or apoptosis of T and B cells.
i. Fas apoptosis pathway mutations result in autoimmune lymphoproliferative
syndrome (ALPS).
5. Regulatory T cells suppress autoimmunity by blocking T-cell activation and
producing anti-inflammatory cytokines (IL-10 and TGF-β ).
i. CD25 polymorphisms are associated with autoimmunity (MS and type
1DM).
ii. FOXP3 mutations lead to IPEX syndrome (Immune dysregulation,
Polyendocrinopathy, Enteropathy, X-linked).
C. More common in women; classically affects women of childbearing age
1. Estrogen may reduce apoptosis of self-reactive B cells.
D. Etiology is likely an environmental trigger in genetically-susceptible individuals.
1. Increased incidence in twins
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18 FUNDAMENTALS OF PATHOLOGY

"Hispanic" est un 2. Association with certain HLA types (e.g., HLA-B27) and PTPN22 polymorphisms
Personne origine 3. Environmental triggers lead to bystander activation or molecular mimicry.
d'Amérique du Sud E. Autoimmune disorders are clinically progressive with relapses and remissions and
often show overlapping features; partially explained by epitope spreading

La rémission est la II. SYSTEMIC LUPUS ERYTHEMATOSUS
A. Chronic, systemic autoimmune disease
réduction ou la
1. Flares and remissions are common.
disparition des signes B. Classically arises in middle-aged females, especially African American and Hispanic
et symptômes d'une women
maladie. 1. May also arise in children and older adults (less dramatic gender bias)
C. Antigen-antibody complexes damage multiple tissues (type III HSR).
“flare” is a worsening 1. Poorly-cleared apoptotic debris (e.g., from UV damage) activates self-reactive
of the disease lymphocytes, which then produce antibodies to host nuclear antigens.
process 2. Antigen-antibody complexes are generated at low levels and taken up by dendritic
cells.
Raynaud 3. DNA antigens activate TLRs, amplifying immune response (IFN-α).
phenomenon----> 4. Antigen-antibody complexes are subsequently generated at higher levels and
Vasospasme of the deposit in multiple tissues causing disease.
5. Deficiency of early complement proteins (C1q, C4, and C2) is associated with
capillaires SLE.
D. Almost any tissue can be involved. Classic findings include
1. Fever, weight loss, fatigue, lymphadenopathy, and Raynaud phenomenon
2. Malar 'butterfly' rash (Fig. 2.4A) or discoid rash (Fig. 2.4B), especially upon
exposure to sunlight
3. Oral or nasopharyngeal ulcers (usually painless)
4. Arthritis (usually involving ≥ 2 joints)
5. Serositis (pleuritis and pericarditis)
6. Psychosis or seizures
7. Renal damage
i. Diffuse proliferative glomerulonephritis is the most common and most severe
form of injury.
ii. Other patterns of injury (e.g., membranous glomerulonephritis) also occur.
8. Anemia, thrombocytopenia, or leukopenia (type II HSR)
9. Libman-Sacks endocarditis
10. Antinuclear antibody (ANA; sensitive, but not specific)
11. Anti-dsDNA or anti-Sm antibodies (highly specific)
E. Antiphospholipid antibody is associated with SLE (one-third of patients).
1. Autoantibody directed against proteins bound to phospholipids

Fig. 2.4A Malar 'butterfly' rash, SLE. Fig. 2.48 Discoid rash, SLE.
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Inflammation, Inflammatory Disorders, and Wound Healing 19

2. Important antiphospholipid antibodies include anticardiolipin (false-positive
VDRL and RPR syphilis screening tests), anti-β2-glycoprotein I, and lupus
anticoagulant (falsely-elevated PTT).
F. Antiphospholipid antibody syndrome is characterized by hypercoagulable state due
to antiphospholipid antibodies (especially lupus anticoagulant).
1. Results in arterial and venous thrombosis including deep venous, hepatic vein,
placental (recurrent pregnancy loss), and cerebral (stroke) thrombosis
2. Requires lifelong anticoagulation
3. Associated with SLE; however, more commonly occurs as a primary disorder
G. Antihistone antibody is characteristic of drug-induced lupus.
1. Procainamide, hydralazine, and isoniazid are common causes.
2. ANA is positive by definition.
3. CNS and renal involvement are rare.
4. Removal of drug usually results in remission.
H. First-line treatment includes avoiding exposure to direct sunlight and
glucocorticoids for flares; other immunosuppressive agents are useful in severe or
refractory disease.
I. 5-year survival is > 90%; renal failure, infection, and accelerated coronary
atherosclerosis (occurs late) are common causes of death.

III. SJÖGREN SYNDROME
A. Autoimmune destruction of lacrimal and salivary glands
1. Lymphocyte-mediated damage (type IV HSR) with fibrosis
B. Classically presents as dry eyes (keratoconjunctivitis sicca), dry mouth (xerostomia),
and recurrent dental caries in an older woman (50-60 years)-"Can't chew a cracker,
dirt in my eyes"
1. May progress to ulceration of corneal epithelium and oral mucosa
C. Can be primary (sicca syndrome) or associated with another autoimmune disorder,
especially rheumatoid arthritis
1. Rheumatoid factor is often present even when rheumatoid arthritis is absent.
D. Characterized by ANA and anti-ribonucleoprotein antibodies (anti-SSA/Ro and
anti-SSB/La)
1. Anti-SSA and anti-SSB are associated with extraglandular manifestations (e.g.,
neuropathy).
2. Pregnant women with anti-SSA are at risk for delivering babies with neonatal
lupus and congenital heart block.
3. Anti-SSA and anti-SSB are also seen in a subset of patients with SLE (screen
pregnant patients)
E. Lymphocytic sialadenitis on lip biopsy (minor salivary glands) is an additional
diagnostic criterion (Fig. 2.4C).
F. Increased risk for B-cell (marginal zone) lymphoma, which presents as unilateral
enlargement of the parotid gland late in disease course

IV. SYSTEMIC SCLEROSIS (SCLERODERMA)
A. Autoimmune disorder characterized by sclerosis of skin and visceral organs
1. Classically presents in middle-aged females (30-50 years)
B. Fibroblast activation leads to deposition of collagen.
1. Autoimmune damage to mesenchyme is possible initiating event.
2. Endothelial dysfunction leads to inflammation (increased adhesion molecules),
vasoconstriction (increased endothelin and decreased NO), and secretion of
growth factors (TGF-β and PDGF).
3. Fibrosis, initially perivascular, progresses and causes organ damage.
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20 FUNDAMENTALS OF PATHOLOGY

C. Limited type-Skin involvement is limited (hands and face) with late visceral
involvement.
1. Prototype is CREST syndrome: Calcinosis/anti-Centromere antibodies,
Raynaud phenomenon, Esophageal dysmotility, Sclerodactyly (Fig. 2.4D), and
Telangiectasias of the skin.
D. Diffuse type-Skin involvement is diffuse with early visceral involvement.
1. Any organ can be involved.
2. Commonly involved organs include
i. Vessels (Raynaud phenomenon)
ii. GI tract (esophageal dysmotility and reflux)
iii. Lungs (interstitial fibrosis and pulmonary hypertension)
iv. Kidneys (scleroderma renal crisis)
3. Highly associated with antibodies to DNA topoisomerase I (anti-Scl-70).

V. MIXED CONNECTIVE TISSUE DISEASE
A. Autoimmune-mediated tissue damage with mixed features of SLE, systemic
sclerosis, and polymyositis
B. Characterized by ANA along with serum antibodies to U1 ribonucleoprotein

WOUND HEALING
I. BASIC PRINCIPLES
A. Healing is initiated when inflammation begins.
B. Occurs via a combination of regeneration and repair

II. REGENERATION
A. Replacement of damaged tissue with native tissue; dependent on regenerative
capacity of tissue
B. Tissues are divided into three types based on regenerative capacity: labile, stable, and
permanent.
C. Labile tissues possess stem cells that continuously cycle to regenerate the tissue.
1. Small and large bowel (stem cells in mucosal crypts, Fig. 2.5)
2. Skin (stem cells in basal layer, Fig. 2.6)
3. Bone marrow (hematopoietic stem cells)
D. Stable tissues are comprised of cells that are quiescent (G 0) , but can reenter the cell
cycle to regenerate tissue when necessary.
1. Classic example is regeneration of liver by compensatory hyperplasia after partial
resection. Each hepatocyte produces additional cells and then reenters
quiescence.

Fig. 2.4C Lymphocytic sialadenitis, Sjögren Fig. 2.4D Sclerodactyly, scleroderma. Fig. 2.5 Intestinal crypts.
syndrome.
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Inflammation,
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Disorders and Wound
, and Wound Healing
Healing 21

E. Permanent tissues lack significant regenerative potential (e.g., myocardium, skeletal
muscle, and neurons).

III. REPAIR
A. Replacement of damaged tissue with fibrous scar
B. Occurs when regenerative stem cells are lost (e.g., deep skin cut) or when a tissue
lacks regenerative capacity (e.g., healing after a myocardial infarction, Fig. 2.7)
C. Granulation tissue formation is the initial phase of repair (Fig. 2.8).
1. Consists of fibroblasts (deposit type III collagen), capillaries (provide nutrients),
and myofibroblasts (contract wound)
D. Eventually results in scar formation, in which type III collagen is replaced with type
I collagen
1. Type III collagen is pliable and present in granulation tissue, embryonic tissue,
uterus, and keloids.
2. Type I collagen has high tensile strength and is present in skin, bone, tendons,
and most organs.
3. Collagenase removes type III collagen and requires zinc as a cofactor.

IV. MECHANISMS OF TISSUE REGENERATION AND REPAIR
A. Mediated by paracrine signaling via growth factors (e.g., macrophages secrete
growth factors that target fibroblasts)
B. Interaction of growth factors with receptors (e.g., epidermal growth factor with
growth factor receptor) results in gene expression and cellular growth.
C. Examples of mediators include
1. TGF-α - epithelial and fibroblast growth factor
2. TGF-β - important fibroblast growth factor; also inhibits inflammation
3. Platelet-derived growth factor - growth factor for endothelium, smooth muscle,
and fibroblasts
4. Fibroblast growth factor - important for angiogenesis; also mediates skeletal
development
5. Vascular endothelial growth factor (VEGF) - important for angiogenesis

V. NORMAL AND ABERRANT WOUND HEALING
A. Cutaneous healing occurs via primary or secondary intention.
1. Primary intention-Wound edges are brought together (e.g., suturing of a
surgical incision); leads to minimal scar formation
2. Secondary intention-Edges are not approximated. Granulation tissue fills the
defect; myofibroblasts then contract the wound, forming a scar.
B. Delayed wound healing occurs in
1. Infection (most common cause; S aureus is the most common offender)

Fig. 2.6 Basal layer of skin. Fig. 2.7 Myocardial scarring. (Courtesy of Fig. 2.8 Granulation tissue.
Aliya Husain.MD)
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22 FUNDAMENTALS OF PATHOLOGY

2. Vitamin C, copper, or zinc deficiency
i. Vitamin C is an important cofactor in the hydroxylation of proline and
lysine procollagen residues; hydroxylation is necessary for eventual collagen
cross-linking.
ii. Copper is a cofactor for lysyl oxidase, which cross-links lysine and
hydroxylysine to form stable collagen.
iii. Zinc is a cofactor for collagenase, which replaces the type III collagen of
granulation tissue with stronger type I collagen.
3. Other causes include foreign body, ischemia, diabetes, and malnutrition.
C. Dehiscence is rupture of a wound; most commonly seen after abdominal surgery
D. Hypertrophic scar is excess production of scar tissue that is localized to the wound
(Fig. 2.9).
E. Keloid is excess production of scar tissue that is out of proportion to the wound (Fig.
2.10).
1. Characterized by excess type III collagen
2. Genetic predisposition (more common in African Americans)
3. Classically affects earlobes, face, and upper extremities

Fig. 2.9 Hypertrophic scar. (Reprinted with Fig. 2.10 Keloid.
permission, http://emedicine.medscape.com/
article/1128404-overview)
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Principles of Neoplasia 3

NEOPLASIA
I. BASIC PRINCIPLES
A. Neoplasia is new tissue growth that is unregulated, irreversible, and monoclonal;
these features distinguish it from hyperplasia and repair.
B. Monoclonal means that the neoplastic cells are derived from a single mother cell.
C. Clonality was historically determined by glucose-6-phosphate dehydrogenase
(G6PD) enzyme isoforms.
1. Multiple isoforms (e.g., G6PDA, G6PDB, and G6PDC) exist; only one isoform is
inherited from each parent.
2. In females, one isoform is randomly inactivated in each cell by lyonization
(G6PD is present on the X chromosome).
3. Normal ratio of active isoforms in cells of any tissue is 1:1 (e.g., 50% of cells have
G6PDA, and 50% of cells have G6PDB).
4. 1:1 ratio is maintained in hyperplasia, which is polyclonal (cells are derived from
multiple cells).
5. Only one isoform is present in neoplasia, which is monoclonal.
6. Clonality can also be determined by androgen receptor isoforms, which are also
present on the X chromosome.
D. Clonality of B lymphocytes is determined by immunoglobulin (Ig) light chain
phenotype.
1. Ig is comprised of heavy and light chains.
2. Each B cell expresses light chain that is either kappa or lambda.
3. Normal kappa to lambda light chain ratio is 3:1.
4. This ratio is maintained in hyperplasia, which is polyclonal.
5. Ratio increases to > 6:1 or is inverted (e.g., kappa to lambda ratio = 1:3) in
lymphoma, which is monoclonal.
E. Neoplastic tumors are benign or malignant.
1. Benign tumors remain localized and do not metastasize.
2. Malignant tumors (cancer) invade locally and have the potential to metastasize.
F. Tumor nomenclature is based on lineage of differentiation (type of tissue produced)
and whether the tumor is benign or malignant (Table 3.1).

Table 3.1: Examples of Tumor Nomenclature

LINEAGE OF MALIGNANT
BENIGN
DIFFERENTIATION (CANCER)

Epithelium Adenoma Adenocarcinoma

Papilloma Papillary carcinoma

Mesenchyme Lipoma Liposarcoma

Lymphocyte (Does not exist) Lymphoma/Leukemia

Melanocyte Nevus (mole) Melanoma

pathoma.com 23
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i
FUNDAMENTALS OF PATHOLOGY

II. EPIDEMIOLOGY
A. Cancer is the 2nd leading cause of death in both adults and children.
1. The leading causes of death in adults are (1) cardiovascular disease, (2) cancer,
and (3) chronic respiratory disease.
2. The leading causes of death in children are (1) accidents, (2) cancer, and (3)
congenital defects.
B. The most common cancers by incidence in adults are (1) breast/prostate, (2) lung,
and (3) colorectal.
C. The most common causes of cancer mortality in adults are (1) lung, (2) breast/
prostate, and (3) colorectal.

III. ROLE OF SCREENING
A. Cancer begins as a single mutated cell.
B. Approximately 30 divisions occur before the earliest clinical symptoms arise.
C. Each division (doubling time) results in increased mutations.
1. Cancers that do not produce symptoms until late in disease will have undergone
additional divisions and, hence, additional mutations.
2. Cancers that are detected late tend to have a poor prognosis.
3. Screening seeks to catch dysplasia (precancerous change) before it becomes
carcinoma or carcinoma before clinical symptoms arise; efficacy of screening,
however, requires a decrease in cancer-specific mortality.
D. Common screening methods include
1. Pap smear - detects cervical dysplasia (CIN) before it becomes carcinoma
2. Mammography - detects in situ breast cancer (e.g., DCIS) before it invades or
invasive carcinoma before it becomes clinically palpable
3. Prostate specific antigen (PSA) and digital rectal exam - detects prostate
carcinoma before it spreads
4. Hemoccult test (for occult blood in stool) and colonoscopy - detect colonic
adenoma before it becomes colonic carcinoma or carcinoma before it spreads

CARCINOGENESIS
I. BASIC PRINCIPLES
A. Cancer formation is initiated by damage to DNA of stem cells. The damage
overcomes DNA repair mechanisms, but is not lethal.
1. Carcinogens are agents that damage DNA, increasing the risk for cancer.
Important carcinogens include chemicals, oncogenic viruses, and radiation
(Table 3.2).
B. DNA mutations eventually disrupt key regulatory systems, allowing for tumor
promotion (growth) and progression (spread).
1. Disrupted systems include proto-oncogenes, tumor suppressor genes, and
regulators of apoptosis.

II. ONCOGENES
A. Proto-oncogenes are essential for cell growth and differentiation; mutations of
proto-oncogenes form oncogenes that lead to unregulated cellular growth.
B. Categories of oncogenes include growth factors, growth factor receptors, signal
transducers, nuclear regulators, and cell cycle regulators (Table 3.3).
1. Growth factors induce cellular growth (e.g., PDGFB in astrocytoma).
2. Growth factor receptors mediate signals from growth factors (e.g., ERBB2
[HER2/neu] in breast cancer).
3. Signal transducers relay receptor activation to the nucleus (e.g., ras).
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Principles of Neoplasia 25

Table 3.2: Important Carcinogens and Associated Cancers

CARCINOGENIC AGENT ASSOCIATED CANCER COMMENTS

CHEMICALS

Hepatocellular carcinoma Derived from Aspergillus, which can
Aflatoxins
contaminate stored rice and grains

Alkylating agents Leukemia/lymphoma Side effect of chemotherapy
Squamous cell carcinoma of oropharynx and
Alcohol upper esophagus, and hepatocellular
carcinoma

Arsenic Squamous cell carcinoma of skin, lung cancer, Arsenic is present in cigarette smoke.
and angiosarcoma of liver
Exposure to asbestos is more likely to lead to
Asbestos
Lung carcinoma and mesothelioma lung cancer than mesothelioma.

Carcinoma of oropharynx, esophagus, lung, Most common carcinogen worldwide;
Cigarette smoke
kidney, bladder, and pancreas polycyclic hydrocarbons are particularly
carcinogenic.

Nitrosamines Stomach carcinoma Found in smoked foods; responsible for high
rate of stomach carcinoma in Japan
Naphthylamine Urothelial carcinoma of bladder Derived from cigarette smoke

Vinyl chloride Angiosarcoma of liver Occupational exposure; used to make
polyvinyl chloride (PVC) for use in pipes
Nickel, chromium,
Lung carcinoma Occupational exposure
beryllium, or silica

ONCOGENIC VIRUSES

EBV Nasopharyngeal carcinoma, Burkitt lymphoma,
and CNS lymphoma in AIDS
HHV-8 Kaposi sarcoma
HBV and HCV Hepatocellular carcinoma
HTLV-1 Adult T-cell leukemia/lymphoma
High-risk HPV (e.g., Squamous cell carcinoma of vulva, vagina,
subtypes 16, 18, 31, 33) anus, and cervix; adenocarcinoma of cervix

RADIATION

Ionizing (nuclear reactor
accidents and AML, CML, and papillary carcinoma of the Generates hydroxyl free radicals
radiotherapy) thyroid

Nonionizing (UVB Results in formation of pyrimidine dimers in
sunlight is most common Basal cell carcinoma, squamous cell carcinoma, DNA, which are normally excised by
source) and melanoma of skin restriction endonuclease
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26 FUNDAMENTALS OF PATHOLOGY

i. Ras is associated with growth factor receptors in an inactive GDP-bound
state.
ii. Receptor binding causes GDP to be replaced with GTP, activating ras.
iii. Activated ras sends growth signals to the nucleus.
iv. Ras inactivates itself by cleaving GTP to GDP; this is augmented by GTPase
activating protein.
v. Mutated ras inhibits the activity of GTPase activating protein. This prolongs
the activated state of ras, resulting in increased growth signals.
4. Cell cycle regulators mediate progression through the cell cycle (e.g., cyclin and
cyclin-dependent kinase).
i. Cyclins and cyclin-dependent kinases (CDKs) form a complex which
phosphorylates proteins that drive the cell through the cell cycle.
ii. For example, the cyclinD/CDK4 complex phosphorylates the retinoblastoma
protein, which promotes progression through the G 1 /S checkpoint.

III. TUMOR SUPPRESSOR GENES
A. Regulate cell growth and, hence, decrease ("suppress") the risk of tumor formation;
p53 and Rb (retinoblastoma) are classic examples.
B. p53 regulates progression of the cell cycle from G1 to S phase.

Table 3.3: Important Oncogenes and Associated Tumors

FUNCTION MECHANISM ASSOCIATED TUMOR

GROWTH FACTOR

PDGFB Platelet-derived growth factor Overexpression, autocrine loop Astrocytoma

GROWTH FACTOR RECEPTORS

ERBB2 [HER2/ Epidermal growth factor
Amplification Subset of breast carcinomas
neu] receptor

MEN 2A, MEN 2B and sporadic
RET Neural growth factor receptor Point mutation
medullary carcinoma of thyroid

KIT Stem cell growth factor receptor Point mutation Gastrointestinal stromal tumor

SIGNAL TRANSDUCERS

Carcinomas, melanoma, and
RAS gene family GTP-binding protein Point mutation
lymphoma

ABL Tyrosine kinase t(9;22) with BCR CML and some types of ALL

NUCLEAR REGULATORS
c-MYC Transcription factor t(8;14) involving IgH Burkitt lymphoma
N-MYC Transcription factor Amplification Neuroblastoma
L-MYC Transcription factor Amplification Lung carcinoma (small cell)

CELL CYCLE REGULATORS

CCND1 (cyclin
Cyclin t(11;14) involving IgH Mantle cell lymphoma
D1)

CDK4 Cyclin-dependent kinase Amplification Melanoma
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Principles of Neoplasia 27

1. In response to DNA damage, p53 slows the cell cycle and upregulates DNA
repair enzymes.
2. If DNA repair is not possible, p53 induces apoptosis.
i. p53 upregulates BAX, which disrupts Bcl2.
ii. Cytochrome c leaks from the mitochondria activating apoptosis.
3. Both copies of the p53 gene must be knocked out for tumor formation (Knudson
two-hit hypothesis).
i. Loss is seen in > 50% of cancers.
ii. Germline mutation results in Li-Fraumeni syndrome (2nd hit is somatic),
characterized by the propensity to develop multiple types of carcinomas and
sarcomas.
C. Rb also regulates progression from G1 to S phase.
1. Rb "holds" the E2F transcription factor, which is necessary for transition to the S
phase.
2. E2F is released when RB is phosphorylated by the cyclinD/cyclin-dependent
kinase 4 (CDK4) complex.
3. Rb mutation results in constitutively free E2F, allowing progression through the
cell cycle and uncontrolled growth of cells.
4. Both copies of Rb gene must be knocked out for tumor formation (Knudson two-
hit hypothesis).
i. Sporadic mutation (both hits are somatic) is characterized by unilateral
retinoblastoma (Fig. 3.1).
ii. Germline mutation results in familial retinoblastoma (2nd hit is somatic),
characterized by bilateral retinoblastoma and osteosarcoma.

IV. REGULATORS OF APOPTOSIS
A. Prevent apoptosis in normal cells, but promote apoptosis in mutated cells whose
DNA cannot be repaired (e.g., Bcl2)
1. Bcl2 normally stabilizes the mitochondrial membrane, blocking release of
cytochrome c.
2. Disruption of Bcl2 allows cytochrome c to leave the mitochondria and activate
apoptosis.
B. Bcl2 is overexpressed in follicular lymphoma.
1. t(14;18) moves Bcl2 (chromosome 18) to the Ig heavy chain locus (chromosome
14), resulting in increased Bcl2.
2. Mitochondrial membrane is further stabilized, prohibiting apoptosis.
3. B cells that would normally undergo apoptosis during somatic hypermutation in
the lymph node germinal center accumulate, leading to lymphoma.

Fig. 3.1 Retinoblastoma. (Courtesy of Jerome Fig. 3.2 Carcinoma involving lymph node. Fig. 3.3 Seeding of the omentum by carcinoma.
Taxy, MD) (Courtesy of Jerome Taxy, MD)
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28 FUNDAMENTALS OF PATHOLOGY

V. OTHER IMPORTANT FEATURES OF TUMOR DEVELOPMENT
A. Telomerase is necessary for cell immortality.
1. Normally, telomeres shorten with serial cell divisions, eventually resulting in