Introduction to Clinical Medicine and Pathology (PDF)

Summary

These lecture notes from UTSA cover the basics of clinical medicine and pathology, as well as a brief history of medical practices. The document outlines various clinical tests, discusses the four pillars of understanding disease, as well as tissue responses to stress. It also explains mechanisms of tissue injury, and wound healing, and how to recognize diseases via alteration, histology, or cytology.

Full Transcript

MMI 3013/HON 3253/MMI 6613 Intro to Clinical Medicine Lecture 1

Introduction to Clinical
Medicine and Pathology
(and a little history)

Thomas G. Forsthuber, M.D. Dr. Med.
Professor of Immunology
Office: BSE 3.250B
Office hours: Monday, 4:30 – 5:30 PM per Zoom or in-person
E-mail: [email protected]

How the class works:
This course will be more fun if you participate
This course is an introductory course to human diseases and
underlying disease concepts
Ask if you have questions
First, we will discuss basic medical/pathological principles.
Then we will discuss specific diseases During each lecture we will present a “case of the day”
Illness does not look pretty. Be prepared for some graphic images. We will do Kahoots for review and fun
This is the nature of medicine. You have been warned. There will be 4 multiple choice exams. Best 3 out of 4 count for
The syllabus for the class explains the most important questions grade.
Attendance at in-person lectures is required. Grading scheme and other information is in the syllabus
Follow University Health and Safety guidelines (e.g. Covid, Flu) Recording of class content including live lectures is not
Handouts will be posted on Canvas (before class if possible) allowed except under conditions outlined in syllabus.
Exams are based on handouts. Please don’t take pictures.
We will use parscore forms for exams Distribution of lecture content, including live lectures, is
Grades will be posted ASAP after the exam strictly prohibited.
No extra credit or make-up exams
Second course will be offered during Spring semester with
additional medical concepts in a group-based case presentation
format (BIO 4473, Advanced Clinical Medicine). Pre-req is the
present course.
Handouts for the lectures will be posted before (if possible) each class

Suggested Books for additional reading:

Kumar, Abbas, Aster: Robbins Basic Pathology (Elsevier-Sounders,
10th edition or higher, ISBN 9780323353175; suggested) (~$91.99)

Kumar, Abbas, Fausto, Aster: Pathologic Basis of disease (Elsevier-
Sounders, 8th edition or higher, ISBN 978-1-4160-3121-5)

MedScape for further readings: https://www.medscape.com/for-you

StatPearls: https://www.ncbi.nlm.nih.gov/books/NBK430685/

Fun facts:
The beginnings of “medicine”
Today we will: Chinese traditional medicine over 5000 years old
The Sumerians (Mesopotamia/today Syria/Iraq)
and Egyptians knew about disease states and
Briefly talk about the history of medicine had healers and specialists (3000 BC)
Introduce some important and useful general medical Diseases were caused by bad spirits, worms,
principles intestinal decay, punishment from the gods
Today
Introduce common clinical lab and diagnostic tests Greece is generally considered the cradle of
modern Western medicine
Greek medicine moved away from
“supernatural” to natural causes, observation
and logical thinking
Greek Medicine revolved around the four
“humors”: blood, phlegm, yellow bile, black bile.
Not “science” but a step to form theories
Greeks did not test their theories (no human
anatomical studies or autopsies).
 Imhotep
Edwin Smith Papyrus

© Jeff Dahl - Fragment from the Edwin-Smith Papyrus
Two noteworthy ancient doctors

Imhotep – “the one who comes in peace” (probably 2650 BC):
pyramid builder and physician to the pharaoh
Professional title: “Shepherd of the anus”

Hippocrates (460-377 BC) founded a school of physicians whose
writing have been preserved. He is credited with the Hippocratic
Oath. He was instrumental in developing the four-humor theory.

Earliest known writing on medicine
Purchased in 1862 by Edwin Smith, American Egyptologist, from Mustafa Agha
Imhotep speculated to be original author
Includes information on trauma surgery, anatomy, diagnosis and treatment of 48
medical conditions including heart failure!
Imhotep rejected “magic” in favor of science for healing

Romans advanced Greek medicine
Hippocrates (460 BC)
Celsus (Aulus Celsus, roman writer/physician: 30 BC – 38 AD)
identified the cardinal signs of inflammation.
– He translated the work cancer from “crab” like growth
described by the Greeks (Hippocrates).
– He wrote “De Medicina”, a book on surgery, diet, pharmacy,
etc. which still exists.

Galen (Claudius Galenus, 129-201 AD, Greek physician.
Considered one of the greatest physicians of all times. He
worked as a physician to the Roman gladiators. His writings
guided medicine for 1,500 years into the Middle Ages. Worked
for roman emperor Claudius Aurelius and his son.

Was the first to describe that:
Arteries are filled with blood instead of “pneuma” (air).
Urine is produced by kidneys
Hippocratic Oath Spinal cord and spinal nerves control muscle function
Hippocratic school taught careful observation, careful The heart is the origin of blood vessels, brain origin of nerves
reporting of symptoms, use of observation for Sensory nerves are different from motor nerves
prognostication Since he couldn’t do autopsies on humans so he got some facts
Instrumental in developing the theory of the four humors wrong (he studied monkeys).
 Edward Jenner (1749-1823)
Medicine transforms into a science:
Introduced first systematic vaccination
Medicine did not advance beyond the teachings of Galen until the He discovered that cowpox could protect against smallpox
Renaissance (13th – 14th century) – no substantial advancements)

Leonardo da Vinci (1452-1519) learned from human dissection about the
functions of muscles, bones, and tendons.

William Harvey (1578-1657) Discovered that the blood is moved through
the body by the heart (famous book ‘De Motu Cordis et Sanguinis’)

Rudolf Virchow (1821-1905) introduced the concept of cellular pathology –
diseases arise from alterations within cells and tissues using microscopic
observation

Ignaz Semmelweis (1818-1865) Robert Koch (1843-1910)
Founder of modern bacteriology
Established that sanitary conditions in surgery and the
healthcare setting saves countless lives
He compared childbed fever in maternity wards staffed by
midwife vs doctors and medical students
He became known as the “savior of mothers”

Discovered causes of tuberculosis, cholera, anthrax
 Louis Pasteur (1822-1895) The first “cellular pathologist”: Rudolf Virchow

Ilustrierte Zeitung Berlin, 1902
Virchow is frequently called the “Father of modern Pathology”
Credited with first recognizing leukemia
Virchow’s node: enlarged left supra-clavicular lymph node as early sign of gastric
cancer
Discovered principles of vaccination, fermentation, and pasteurization Discovered pulmonary thromboembolism (he coined the term embolism)
Discovered first vaccines for rabies and anthrax Founded cellular pathology and encouraged his students to think “cellular” and use
microscopes
“The only source for a living cell is another living cell”

Sir Joseph Lister (1827-1912)
Sigmund Freud (1856-1939)
Father of psychoanalysis Father of antiseptic surgery
Used phenol to sterilize instruments, wounds, dressings
 George Papanicolaou (1883-1962) Sir Alexander Fleming (1881-1955)

He discovered that vaginal smear could detect uterine cancer (1943) Discovery of penicillin and research on lysozyme
He was a pioneer in early cancer detection He noticed in 1928 that mold (Penicillium notatum) inhibited the growth of
Staphylococcus aureus on a culture plate

Basic Principles of Human Disease The four pillars to understanding disease:
Human diseases in the broadest sense are undesired deviations from the Disease etiology: the cause(s) of a disease.
norm (the “generally accepted standard”) – Infection, injury, genetic defects,
– Example: Streptococcus pneumonia infection of the lungs
Diseases are usually detected if they cause signs or symptoms
Pathogenesis: the disease process
– Signs: Fever, high blood pressure, bleeding = can be seen by doctor, – Example: Streptococcus infection of the lung leads to lung
detected by clinical tests (for example X-ray) damage, inflammation, fluid accumulation

– Symptoms: pain, drowsiness, vertigo = reported by the patient, cannot Lesion = Morphologic changes/ultrastructural : structural changes in
the affected tissues
be measured.
– Example: Bacterial pneumonia leads to lobar consolidation,
inflammatory infiltrates, lung edema
Some diseases are predetermined: example - genetic defects
Functional changes = impaired function of an organ system =
Some diseases are acquired: example - infection, trauma, degenerative clinical manifestation
– Example: Lobar bronchopneumonia, fever, pain, malaise,
possibly death!
Some diseases can be seen by eye: example - jaundice
Pathogenesis Functional
Some diseases may be visible only with medical tests, imaging: example – Etiology Lesion changes
pigment or inclusions visible in cells by microscope, urine protein.
 How to recognize diseases (pathologic The diagnosis begins with observation
alterations):
A) The right arm is affected
Reported by the patient (e.g. pain, nausea) B) The left arm is affected

Gross examination: The alteration (lesion) is visible by naked eye
(physical examination, autopsy)

Histologic examination: Alterations are visible by microscope

Laboratory examination: e.g. blood tests, urine sample, DNA test

Specialized examinations: X-ray, ultrasound, endoscopy, magnetic
resonance imaging,

The scientific foundation for the cardinal signs of inflammation:
The “old” physicians recognized “disease”: The four phases of acute inflammation:
Celsus (30 BC – 38 AD) I. 0 – 4 hours: preformed factors:
The four cardinal signs of acute inflammation: Antibodies, complement, serum
Calor (heat) factors, vasoactive factors,
Dolor (pain) CS: RUBOR, CALOR,
Rubor (redness)
II. 4 - 48 hours: influx of
Tumor (swelling) neutrophils
CS: RUBOR, CALOR, DOLOR,
Galen (129-201 AD) TUMOR
Fifth sign: functio laesa = Downloaded from: Robbins & Cotran Pathologic Basis of Disease (on 14 August 2006 10:46 PM)

III. 24-96 hours: influx of
Impaired function
macrophages
CS: RUBOR, CALOR, DOLOR,
TUMOR, FUNCTIO LAESA
WebPath
IV. > 96 hours: adaptive immunity:
T lymphocytes are activated and migrate to
inflammatory site
CS: DOLOR, TUMOR, FUNCTIO LAESA
 Intro to Clinical Medicine
Before we test:
How do we arrive at a clinical diagnosis?

Diagnostic Tests Information about the current illness/problem of the
patient
– Most important: is it an emergency/life threatening

The patient history

Thomas G. Forsthuber, M.D. Dr. Med.
The physical examination
Professor of Immunology, Adjunct Professor of Molecular
Microbiology, and Immunology
Office: BSE 3.250B Diagnostic tests
E-mail: [email protected]
Office Hours: Monday 4:30 – 5:30 pm

Current illness: The patient history
When did the symptoms/signs start? Circumstances?
– Current and past medical history
Is this the first time the patient had these symptoms? – Are there other concurrent medical
problems?
Are the symptoms getting worse, better, or remain stable? – Other patient issues that could be relevant:
Smoking?
What steps did the patient take? Did anything help or change? Alcohol, Drugs
Social issues, employment, job loss
If the patient had this in the past, was there a significant change? – Family history
– Any other information that might help with
the case
 The physical examination Diagnostic tests and procedures

– Cultivate the art of observation Non-invasive procedures:
– Be systematic in your examination – Eye/ear/throat inspection, neurological test of reflexes,
– Develop a routine that you follow – Urine test, throat swab
– Know your tools (i.e. the stethoscope!) – X-ray, ultrasound, MRI, CT, ECG,
– The future: mobile ultrasound devices – Note: If it does not break the skin it is considered non-invasive
(fancy!)

Invasive procedures:
– Blood draw, spinal tap, biopsy, endoscopy,
– Note: If it breaks the skin it is considered invasive!

Note: There is no generally accepted definition for “invasive procedure”

I. Common Lab tests:
Common blood tests:
- CBC – Complete blood count (+ Diff) Other important lab tests:
- CMP - Comprehensive metabolic panel - Urine: protein, microorganisms, pH, blood,
Electrolytes (Na, K, Cl, Ca), glucose, - Stool – blood, parasites, fat
blood urea nitrogen (BUN), creatinine - Cerebrospinal fluid, cells, proteins, microorganisms
(Crea), liver enzymes (AST, ALT), etc.
- Plasma proteins (albumin, enzymes,
immunoglobulins
- Antibodies (serologic tests)
- Hormones (e.g. thyroid hormones)
- Disease biomarkers (e.g. for myocardial
infarct, pancreatitis, liver disease, renal
Pictures courtesy WebPath (Utah)
disease) Dr. Edward Klatt, MD

- Erythrocyte sedimentation rate = ESR (today
only useful for myeloma, temporal arteritis,
polymyalgia rheumatica)
- Drugs
 Blood is routinely analyzed in medicine White Blood Cells (WBC)
Sysmex analyzer for CBC (complete blood count): Blood: CBC (complete blood count):

RBC: 5 x 10e6/ul
Hb: g/100 ml (normal 14
– 16 g/ dL = dL = 100 ml
(1/10 of a liter)

Pictures courtesy WebPath (Utah)
Dr. Edward Klatt, MD

Common terms for abnormal CBC
CBC in medical charts (Fishbone)
Type of Cell Increase Decrease

erythrocytosis or anemia or
Red Blood Cells (RBC)
polycythemia erythroblastopenia

White Blood Cells
Hgb
leukocytosis leukopenia
(WBC): 16
-- lymphocytes -- lymphocytosis -- lymphocytopenia

WBC Plt
-- granulocytes: -- granulocytosis
-- granulocytopenia or 8.9 275
agranulocytosis

-- --neutrophils -- --neutrophilia -- --neutropenia
-- --eosinophils -- --eosinophilia -- --eosinopenia
Platelets thrombocytosis thrombocytopenia
All cell lines --- pancytopenia

www.wikipedia.com
 II. Measuring electrical activity for diagnostic
purposes
Electrocardiogram (ECG, EKG): Measures electrical activity of the
heart
Electroencephalogram (EEG): electrical activity of the brain
Electromyogram (EMG): electrical activity of muscle
lused in Neurology to diagnose Als , Ms , mysthenia gravis)

ECG
(also EKG)

Electric conduction of the heart Typical ECG strip

Sinus node
QRS (+)

(SA node)
ECG
T
AV node
P
P wave: atrial depolarization

-controlledbea QRS complex: ventricular depolarization
T wave: repolarization of the ventricle
SA node = sinoatrial node
AV node = atrioventricular node
Mnemonic: Dog and the cookie
 II. Measuring electrical activity
ST-elevation in MI
Not good:

Bad:
Ventricular flutter
250-300 beats/min
Sinusoidal waves
V-FIB

Worse: Ventricular
Fibrillation: no clear
electrical activity
 Intro to Clinical Medicine

Diagnostic Tests Part 2
Thomas G. Forsthuber, M.D. Dr. Med.
Professor of Immunology, Adjunct Professor
of Molecular Microbiology, and Immunology
Office: BSE 3.250B
E‐mail: [email protected]
Office Hours: Monday 4:30 – 5:30 pm

X‐Ray examination
‐ X‐rays were discovered by Wilhelm Roentgen in 1895.
‐ He worked with electron beams (a cathode‐ray tube) in his lab and
discovered that a fluorescent screen nearby started glowing.
‐ He found that X‐rays could go through tissue, but not bones and metal,
and could expose photographic film.
‐ X‐rays (and gamma rays) are electromagnetic radiation (photons)
similar to light but of much shorter wavelength (much higher energy
level).
‐ Light has wavelength of 6000 angstroms, X‐rays are 1 angstrom (0.1
nm), and gamma rays are 0.0001 angstrom.
‐ X‐rays and ionizing radiation is measured in Sievert (Sv).
‐ It used to be measure in rem (Roentgen equivalent in man).
‐ Sievert is used to measure the radiation dose to the human body
‐ 1 Sv = 100 rem
‐ 1 rem = 0.01 Sv
 How much
radiation is
dangerous?
Chernobyl control 1Sv = 100 rem
room: 300 Sv/hr
(30,000 rem)
Death in 1 minute! Equal to 1,000
chest x‐rays

Chernobyl control
room tourism:
Equal to 20 chest
1.13 mSv/5 x‐rays
minutes ~10 X‐
rays per 5
minutes

X‐ray continued

X-ray photons
 Digitizing of X‐ray images with photostimulable phosphor plates

Excited electrons trapped in
phosphor “color centers” ‐>

Luminescence ‐> Source: Wiki

Computed tomographic Scan (CT)

https://www.youtube.com/watch?v=l9swbAtRRbg
CT uses motorized scanner that circles around patient
CT obtains many serial x‐ray images that are then compiled to a 3‐D image
Intermountain Medical Imaging, Boise, Idaho
CT can reveal much more details than X‐ray
Individual scans of CT (serial images) use lower intensity x‐rays
But – overall X‐ray exposure is significantly higher with CT than X‐ray
Enhanced X‐ray studies with contrast material

Brain Aneurysm
After treatment

Nuclear Medicine
Patients are injected with radioactive material (e.g. I-131) that is then
enriched in areas of highest activity.

Thyroid adenoma Metastatic cancer of thyroid
Magnetic resonance imaging (MRI)

https://www.youtube.com/watch?v=1CGzk‐nV06g
 Note:
MRI uses strong magnets – no magnetic material in the room
MRI machines are very noisy – patients get earplugs or
headphones
MRI is superior for viewing soft tissues
MRI images can be “weighted” based on the structures that they
should enhance by timing of the RF pulse.
T1 – One tissue is bright – fat
T2 – Two tissues are bright – fat and water
T1 is better for anatomy, T2 is better for pathology
MRI can be used with contrast materials – Gadolinium
Enhances visibility of structures such as blood vessels

Courtesy GeekyMedics

T1 – ONE tissue is bright: fat
T2 – TWO tissues are bright: fat and water (WW2 – Water is
White in T2)
 Same tissue, different methods

CT MRI PET
Computed Magnetic resonance Positron Emission
Tomography Imaging Tomography

Noninvasive Noninvasive Injection of
Uses:
X-rays Magnetic and radiowave radioactive material
fields gamma-rays
CAT scan = Computer Axial Tomography
 Ultrasound
Ultrasound uses a transducer to generate high‐frequency sound
waves (>20,000 Hz) to detect tissues in the body
Humans cannot hear these sound waves
These soundwaves generate echo's that are reflected back differently
to the transducer because tissues in the body have different densities
Ultrasound (sonography) can be used for many human conditions
(heart conditions, blood vessels, internal organs, etc.)
Ultrasound is painless and works through the skin

https://www.youtube.com/watch?v=I1Bdp2tMFsY
 Biopsy, Histology, Cytology
Biopsies are performed to obtain tissue for histologic examination.
Example: Breast biopsy, bone marrow biopsy

Histology: examination of tissue with the microscope. Tissue is intact
and morphology preserved

Cytology: Cells are recovered by various means. Single cells are
usually recovered and tissue structure is not preserved.
Example: pap smear, bronchoalveolar lavage (BAL), urine cytology

Histology:
Skin

www.brooksidepress.org
Cytology:
Pap smear
 Tissue processing
Clinicians (or Pathologists) remove tissue by needle
or surgery and preserve it in a fixative or frozen for
examination by the pathologist.
Upon receiving of the tissue, the pathologist
inspects the tissue, describes the tissue, marks the
tissue, and dissects the tissue.

Pictures courtesy WebPath (Utah)
Dr. Edward Klatt, MD

Tissue processing
Tissues must be processed before sections can be
obtained for histologic examination.
Tissues are frequently embedded in paraffin
Another way to process tissue is called “frozen
section”. Frozen section is frequently done during
surgery to give the surgeon fast information needed
for his work.
Frozen section: Quick freezing of the tissue in
butanol/liquid nitrogen.

Pictures courtesy WebPath (Utah)
Dr. Edward Klatt, MD
 Sections must be stained for
examination
Sections must be stained with dyes before they can
be examined by the pathologist
Most common stain is H&E (Hematoxylin and Eosin).
Hematoxylin is a basic dye and stains nucleic acid in
the cell nucleus blue. Eosin (acidic) stains the
cytoplasm reddish/pink.

Pictures courtesy WebPath (Utah)
Dr. Edward Klatt, MD

Special stains
H&E

Some tissue structures are
difficult to see with standard
H&E
“Special stains” help
PAS
discriminate particular
tissues
PAS (periodic acid Schiff)
staining: Detection of
glycogen in liver or muscle.
Fungi also stain PAS positive.
Masson’sTrichrome staining:
collagen (for example liver Trichrome
cirrhosis)
 Immunofluorescence staining

IF staining can
specifically identify
particular cell types,
tissues, molecules
Example:
Immunoglobulins and
complement in post‐
infectious
glomerulonephritis
 Intro to Clinical Medicine Lecture (3)

Mechanisms of tissue injury

Thomas G. Forsthuber, M.D. Dr. Med.
Professor of Immunology
Office: BSE 3.250B
E-mail: [email protected]
Office Hours: Monday 4:30 – 5:30 – ZOOM link Canvas

Pathological Diagnosis based on macroscopic/microscopic changes
Living cells and tissues adapt to a changing
environment or stress
Failure of adaptive mechanisms leads to cell injury or
cell death.
Cellular changes/injury can be visible at the organ or
at the cellular level
Tissues can also show changes related to aging
Macroscopic or microscopic changes to tissues are
important for pathological diagnosis
Macroscopic changes (Organ level):
– Hypertrophy, atrophy, dysplasia
– Pigmentation, calcification
– Fatty change
Microscopic changes (Cellular level)
– Pigmentation, inclusions (e.g. iron, fat, Lipofuscin)
– Multi-nucleation
– Apoptosis, necrosis
 Macroscopic changes in liver disease

Which one is the “fatty” Liver?

A B

Microscopic changes in liver disease

Normal liver Fatty liver

Portal vein
Hyaline inclusions in the liver = Mallory bodies
Alcohol!

Hemosiderin

H&E Prussian blue
(Iron)
 Tissue responses to stress
Increased demand or Hypertrophy, hyperplasia
chronic stimulation
Decreased demand, lack of Atrophy
stimulation

Chronic injury Metaplasia

Hypertrophy: Cells increase in size, organs may increase in size
Hyperplasia: Increase in the number of cells
Atrophy: Shrinkage in cell size (or organ)
Metaplasia: Cells change from one cell type to another

Hypertrophy: In dividing and non-dividing cells
Hyperplasia: Only with dividing cells

Physiologic hypertrophy

Uterus Uterus histology
Pregnant Normal Normal Pregnant
 Pathologic Hypertrophy

Hyperplasia

Prostate Hyperplasia
(Nodular hyperplasia, BPH=
benign prostatic hyperplasia)

Prostate hyperplasia
(proliferation of glands)

Testosterone converted in prostate
stromal cells to dihydrotestosterone
(x10 more potent)
 Atrophy

Physiologic atrophy: Shrinkage of the uterus after pregnancy,
– Mechanism: loss of hormonal stimulation, developmental gene
regulation,

Pathologic atrophy: muscle atrophy after fracture, brain with
Alzheimer's
– Inactivity, loss of innervation, loss of perfusion/blood supply, lack
of nutrition, loss of hormonal stimulation, aging, pressure

Atrophy
A B
 Quick histology primer epithelial cells

Most body surfaces are lined by Epithelial cells

Agnes Lacombe,
University of British Columbia

Three types of epithelium:
“Simple epithelium”
SQUAMOUS Epithelium:
Lining of body cavities,
Vessels, alveoli (lung)

CUBOIDAL Epithelium:
Lining nephrons,
Thyroid glands, surface
of ovaries

COLUMNAR Epithelium:
Gut including stomach &
large intestine, gallbladder,
Lining of uterus
Upper respiratory tract
 Epithelial cells form ONE layer (simple epithelium) or
SHEETS (stratified epithelium)

Single layer Arranged in sheets or layers

Metaplasia
Squamous metaplasia:
Upper airways = smokers
Stress
Columnar Squamous
Epithelium Epithelium

Intestinal metaplasia:
Intestinal metaplasisia
Gastro-esphageal junction=
Barrett’s esophagus

GERD
Squamous Columnar
Epithelium Epithelium
(glandular
type)
 Metaplasia

Curtesy Medbullets

“Fatal” stress – cells die!

Causes of cell death:
Oxygen deprivation
Physical insult (heat,
cold, electric)
Chemical
Infectious
Immune
Genetic
Nutrition

Death by Necrosis Apoptosis
necrosis or Inflammation! Silent!
apoptosis
 Classical apoptosis sign: DNA laddering

Apoptosis

Necrosis
Normal
- Caspase = Cysteine-
Aspartate protease
-Laddering is due to
caspase-activated
Dnase (CAD)
- CAD cuts DNA into
small fragments
- Fragments are
multiples of 280 bp
(length of DNA
wrapped around
histones)

Apoptosis pathways
Extrinsic (death receptor-mediated) apoptosis pathway
Intrinsic (mitochondria-mediated) apoptosis pathway
Third pathway: Endoplasmic reticulum stress pathway (mediated by
too much or to little Ca++)

Extrinsic apoptosis pathway Intrinsic apoptosis pathway
 Necrosis

Violent tissue death: necrosis

Normal tissue Necrotic tissue

Myocardial infarct: ischemic necrosis of myocardium
 Necrosis
Coagulative Necrosis: Liquefactive Necrosis:
“Dry necrosis”. Basic “Liquid necrosis”. Tissue
cell outline maintained. dissolves. Every structure lost.
Nuclei lost, cytoplasm No cells visible.
eosinophil. Hypoxic cell Brain shows liquefactive
death necrosis!
Seen in Infarcts Seen in severe Infections

“Clinical” types of necrosis

Gangrene (gangrenous necrosis):
– Dry or wet gangrene
– Often after loss of blood supply -> coagulative necrosis
– Example: diabetic foot, peripheral arterial disease, frost
bite

Caseous necrosis: Tuberculosis, lung cavity filled with
“cheesy” white-yellow material. -> liquefactive necrosis

Fat necrosis: Fat destruction of the mesentery (tissue-fat-
sheet in the belly). Frequently after pancreatitis.
 Important:
The brain usually shows liquefactive necrosis
Intro to Clinical Medicine

Wound healing

Thomas G. Forsthuber, M.D. Dr. Med.
Professor of Immunology
Office: BSE 3.250B
E-mail: [email protected]
Office Hours: Monday 4:30 – 5:30 – ZOOM link in Canvas

Tissue repair
Inflammation is usually associated with damage/dead tissue
Dead tissue is a potential source of infection and impairs tissue
repair.
Dead tissue must be removed and/or repaired.
Damaged tissue may be completely replaced (“like new”) or
replaced by a scar (“cheap” replacement)
Tissue repair must be well controlled
If repair is excessive new medical issues may arise (e.g. excess
scar formation = keloid or liver cirrhosis)
If tissue inflammatory stimulus continues fibrosis may be result.
 Note:

Tissue regeneration: lost tissue re-grows.
–Occurs in tissues with high turnover – skin, gut, bone marrow
–Rarely occurs in organs, except for the liver (and kidney)
–Depends on intact tissue scaffold
–Requires that “tissue stem cells” survive

Healing:
–Healing is a combination of regeneration and scar formation
–Scar formation is the replacement of original tissue with fibrous tissue

Regeneration
Some tissues, like the liver, can regenerate.
GI and skin epithelium can regenerate completely

Liver donor before Liver donor after transplant:
transplant Liver has regenerated =
compensatory growth
 Regeneration and healing requires tissue
stem cells

Liver stem cells

Growth factors and cytokines in wound healing
Macrophages are architects of wound healing/tissue repair via
cytokines and growth factors

Cytokines and growth factors orchestrate would healing
Growth factors affect:
– cell proliferation
– cell migration
– angiogenesis (growth of blood vessels)
– Tissue matrix formation
– Deposit of collagen = fibrosis

(Some) important growth factors:
– Transforming growth factor beta (TGF-, fibrosis);
– Vascular endothelial growth factor (VEGF, vessels);
 Wound healing
Wound healing is a multistep process

First phase: Inflammatory phase
– removal of damaged/dead tissue

Second Phase: Proliferative phase
– Angiogenesis (new blood vessel formation)
– Granulation tissue formation
– Wound contraction (myofibroblasts)

Third phase: Maturation phase
– Tissue remodeling (collagen)
– Removal of unneeded cells (apoptosis)
– Reconstitution of the extracellular matrix

Wound healing
Inflammatory phase

Proliferative phase Maturation phase
 “Uncomplicated” wound healing
Healing by First intention
Uncomplicated wound:
Edges are close, not infected
Proper epithelialization of wound surface
Angiogenesis
Fibroblast proliferation and collagen
deposition
Remodeling
As good as new – maybe not even scar

“Complicated” wound healing
“Healing by second intention”
Wound has larger gaps
– Infected wound, more tissue
damage, foreign body
More inflammation
More granulation tissue
Wound contraction becomes
important = mediated by
myofibroblasts that contract at the
edges.
Healing is usually less perfect and
leaves scar = fibrous tissue, thinner
epithelial cover
 What impairs wound healing?

Locally
– Impaired perfusion, infection, foreign body, hematomas,
denervation, necrotic tissue, mechanical stress, type of tissue,
surgical technique,

Systemic
– Age, pre-existing conditions (diabetes, malnutrition,
atherosclerosis, drugs (steroids, chemotherapy), genetic
disorders, trauma, vitamin deficiency,

Complications of wound healing (skin)

Healing is incomplete (deficient scar)
– Wound dehiscence = edges of the wound separate
– Ulcer formation = wound does not heal (not epithelialized)

Excessive scar formation
– Hypertrophic scar = raised scar tissue that remains within
boundaries of the original wound
– Keloid = Overgrowth of scare tissue beyond original wound
– Aggressive scars = desmoid tumors (aggressive fibromatosis)
Benign tumors but can grow aggressively and even invade
surrounding tissues. NOT cancer and does not metastasize!

Wound contraction
– Contractures = after burns
 Keloid

Ongoing inflammatory stimulus leads to fibrosis!
Example: Liver cirrhosis
Intro to Clinical Medicine

Inflammation and repair

Thomas G. Forsthuber, M.D. Dr. Med.
Professor of Immunology
Office: BSE 3.250B
E-mail: [email protected]
Office Hours: Monday 4:30 – 5:30 – ZOOM link in Canvas

Inflammation
Inflammation is a mechanism to protect an organism from danger
Typically, this danger comes from invading pathogens (infection) or tissue
damage through other means (necrotic tissue death)
Inflammation is meant to eliminate the source of danger, restrict its extent
(wall off), and help repair the damage

Inflammation has two main components:
– Vascular component
– Cellular component

Based on the timing and the involved cells one can distinguish between
acute and chronic inflammation

The inflammatory response varies to a certain degree between tissues and
organs
 Inflammation:

Without preexisting immunity: preformed
mechanisms and innate immunity are the first line
of defense
With preexisting immunity: adaptive immunity (e.g.
antibodies) facilitates activation of defense
mechanisms

Key events:
ALERT – WALL OFF – DESTROY - REPAIR
First: alarm the body that something is going on!
Second: wall off and prevent the spread of the
pathogens from the entrance site to the blood and
other tissues
Third: bring “troops” to the site of action to destroy
danger
Fourth: Set stage for repair by growing blood
vessels and proliferate fibroblasts

Inflammation cannot (should) not go on indefinitely
The inflammatory process is supposed to stop when the offender is
eliminated
There are specific mechanisms that terminate/restrict an
inflammatory process
In the end, the goal is not to eliminate the offender at the cost of
destroying the host
Therefore: different tissues, different inflammatory responses
 Events that trigger inflammation:

Infections
Trauma (injury)
– Mechanical injury
– Physical injury (heat, frostbite)
– Chemicals
– Foreign bodies
Tissue necrosis
Immune reactions (for example in hypersensitivity disorders)

The big players:
Blood vessels
Inflammatory
cells
Vasoactive
factors (e.g.
Histamine,
Bradykinins)
Complement
system
Blood clotting
system
 Sequence of inflammatory events
Inflammatory events after infection:
Example: Microbes enter tissue through
breach in skin
Microbes are coated with antibodies and/or
complement (see later)
Antibodies bind complement, complement
factors are cleaved and complement cascade
is activated
Complement factors C3a and C5a activate
other cells, such as tissue mast cells
Tissue mast cells release vasoactive factors:
– Histamine = short acting vasodilator,
released early
– Bradykinin = released later, long acting
vasodilator
Vasodilators increase blood flow into tissues,
but speed of blood flow slows down in
affected areas
Immune cells become recruited and
activated.
First cells: Neutrophils
Next: macrophages/DC. They release factors
that induce additional defensive mechanisms,
such as fever (CNS) and acute phase
proteins (liver)

Blood vessels are central players in inflammation:

Vascular dilation and permeability!

Increased blood
flow =
Lesion turns red
and warm!
(Rubor & Calor)
 How to achieve vascular changes:

Inflammatory and noninflammatory cells can produce vasoactive
mediators:

Mediators inducing vascular dilation:
– Histamine, nitric oxide, Bradykinin, prostaglandins, Serotonin
– Primarily act on arterioles (very small arteries) -> more in, less
out!
Mediators that increase vascular permeability:
– Histamine, Bradykinin, Serotonin, complement factors (C3a,
C5a)

Physiology of vascular changes
Normal state:
No fluid excess in tissues
Lymphatic vessels drain excess fluid from tissues

During inflammation
More blood flow and fluid leaks into tissues
 Vascular dilation triggers key tissue events in acute
inflammation
Vascular dilation:
– Altered blood flow creates “turbulence” of blood cells
(marginalization) = inflammatory cells leave the blood stream and
migrate into tissues
– Increased oxygen demand by cells lowers tissue oxygen levels
– Decreased oxygen in tissues results in lower (acidic) pH in
inflamed region = inflammatory enzymes work better
– Altered blood flow promotes blood clot formation to stop bleeding
and wall off injury

Enhanced vascular permeability:
– Inflammatory proteins can get into injured tissue
– Inflammatory cells can easier migrate through vessel walls

Fluid in tissues/cavities is clinically/diagnostically
relevant: Transudate vs. Exudate
Transudate:
- low in protein, 30g/L; specific
gravity > 1.020; cloudy,
- Infections, pneumonia, Tb,
malignancy, pulmonary embolism

Light’s Criteria: Used to differentiate between transudate and exudate
“Fluid” protein to serum protein ratio > 0.5 = exudate

Edema: Transudate or exudate in tissue or body cavities
Pus: Fluid contains many leukocytes (neutrophils, macrophages)
 Antibodies and complement are important to alert
immune defenses and destroy microbes
Complement system consists of over 30 proteins
The are usually activated in sequential order:
C1 -> C2a/C4b -> C3 -> C5, C6, C7, C8, C9
C3 is the central molecule
C3a and C5a serve as soluble signals for other cells

Inflammatory cells migrate to sites of inflammation in a
defined sequence of steps
 Inflammatory mediators produced by phagocytes and liver have
systemic effects

Acute phase reactants trigger acute phase response:

Acute phase reactants:
“positive” = proinflammatory
C-reactive protein (CRP)
Serum amyloid A (SAA)
Complement (C3, C4)
Fibrinogen
Mostly made by liver

“negative” = anti-inflammatory
Transferrin
Albumin

Systemic effects of inflammation
Systemic changes during acute inflammation
are called “acute phase response”
FEVER is induced by endogenous pyrogens
(IL-1, TNF) that induce PGE2 via enhancement
of cyclooxygenase-2.
Acute phase proteins (e.g. CRP, SAA) help in
defense against infection
LEUKOCYTOSIS ( > 10,000 leukocytes/ul
blood)
– Neutrophilia, lymphocytosis, eosinophilia,
INCREASED PULSE/enhanced blood pressure
(BP)
CHILLS, MALAISE,
Very severe change:
– Septic shock syndrome
– Disseminated intravascular coagulation
(DIC)
 Fever = Pyrexia

A person is considered to have fever when:
Rectal temperature (anal) is 38oC or higher (100.4oF)

Oral temperature (mouth) 37.5oC or higher (99.5oF)

Axillary temperature (armpits) 37.2oC or higher (99oF)

Often fever is graded as follows:

low-grade: 38 - 39 °C (99.5 - 102.2 °F)

moderate: 39 - 40 °C (102.2 - 104 °F)

high-grade: > 40 °C (> 104 °F)

Hyperpyrexia: > 42 °C (> 107.6 °F)

Forsthuber’s conversion trick: 40°C = 104°F -> -2°F = -1°C

Acute versus chronic inflammation

Acute inflammation: Neutrophils, necrosis, edema,
Chronic inflammation: lymphocytes, fibrosis,
Acute inflammation Chronic inflammation

Neutrophils Lyphocytes
Dilated vessels Fibrosis
Edema Changes in tissue
architecture