GPT 1.05 - Tissue Renewal & Repair PDF

Summary

This document provides an overview of tissue renewal and repair, focusing on the mechanisms of regeneration and scar formation. It details the factors influencing the repair process and includes a discussion of abnormalities in tissue repair, such as chronic wounds and excessive scar tissue. The document also touches on the role of stem cells and extracellular matrix in tissue healing. It is a general pathology document.

Full Transcript

GENERAL PATHOLOGY
Tissue Renewal and Repair Block 1
Jose Jasper L. Andal, MD | August 12, 2024 Trans 1.05

m

OVERVIEW
I. Overview of tissue repair III. Clinical context Involved in the process that restore function and
A. Mechanisms of tissue A. Healing of skin structures of organs
repair wounds Focuses on two things:
Regeneration IV. Factors that influence ○ Tissue and cell regeneration
Scar formation tissue repair ○ Scar formation
B. Determinants of V. Abnormalities in tissue The fate of the damaged tissue will depend on:
tissue repair repair
○ Nature of injury
Cell proliferation A. Chronic wounds
Ex. trauma, surgery performed
Tissue B. Wound Dehiscence
proliferative C. Excessive scar tissue ○ Cell proliferation
capacity deposition ○ Integrity of the Extracellular Matrix (ECM)
ECM and growth ECM is the connective tissue that binds our
factors cells together
II. Wound healing in the skin
A. Repair by connective Regeneration
tissue deposition ​Some tissues are able to replace the damaged
Steps in Scar components and essentially return to a normal state
Formation May occur through proliferation of differentiated cells
○ Ex. Hepatocytes may undergo either:
⭐ LEGEND
: Important information
Gray Text or : Book information
Simple replication of the existing differentiated
cells, or
Replication of the stem cells → differentiation
💬: Good-to-know info from lecturer
: Processes or Clinical Correlation
into the different component cells of the lost
tissue
BOOK CHAPTERS
Robbins & Cotran Pathologic Basis of Disease (10th edition),
Scar Formation
Chapter 3, pp. 103-112
Tissue repair that involves:
○ Connective tissue deposition
ABBREVIATIONS ○ Fibrosis (collagen deposition)
ECM Extracellular Matrix Important mechanism that fills in gaps, maintain
VEGF Vascular Endothelial Growth Factor structure, blocks pathogens, and prevent further
FGF Fibroblast Growth Factor bleeding from an open area [Batch 2027]
PDGF Platelet Derived Growth Factor To seal off the wound and enable wound contraction
TGF Transforming Growth Factor ○ Ex. burn patient who has formed contractures

I. OVERVIEW OF TISSUE REPAIR B. Determinants of Tissue Repair
A. Mechanisms of Tissue Repair Cell Proliferation

Figure 2. Cell cycle shows how cells proliferate to go back into the

⭐ Key determinant of tissue repair
cell cycle from G0

○ Cells that are not able to proliferate cannot
undergo regeneration
Normally maintains tissue homeostasis
Most of the cell in the adult phase are in the G0
Figure 1. Mechanisms of tissue repair: regeneration and scar
phase
formation. Following mild injury, which damages the epithelium but
not the underlying tissue, resolution occurs by regeneration, but
Some cells have the ability to cycle rapidly
after more severe injury with damage to the connective tissue, repair ○ Ex. bone marrow cells to replace blood elements
is by scar formation

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 GPT 1.05 Tissue Renewal and Repair

Embryonic Stem Cell
Potential source of cells to replace injured tissues
In-vivo (in-utero): different cell lines mature into
every possible tissue in an infant
In-vitro (in laboratory): can be cultured and given
growth factors to become different cell lines
Pluripotent stem cells (PSC)
○ Cells that can differentiate into various cell
lineages through the help of growth factors
○ → Multipotent stem cells → Lineage committed
stem cells →
Endoderm: ex. Foregut, Upper respiratory tract
Mesoderm: ex. Connective tissue
Ectoderm: ex. Skin
○ → Cell culture → Embryonic stem cell →
Pancreatic islet cells (for type 1 diabetics)
Hematopoietic cells (for bone marrow
Figure 5. Mechanisms regulating cell population
transplant)
Cardiomyocytes (for MI patients)
Neurons (for patients with neurodegenerative Skin Epithelium
disease)
Hepatocytes (for Liver diseases)

Figure 6. Skin epithelium
Figure 3. In vivo (totipotent stem cells) and in vitro (embryonic stem
cells) differentiate into different cell types The differentiated keratinocytes are seen on the
surface layer
Tissue/Adult Stem Cells The basal cells present in the stratum basale layer of
A small population of adult stem cells are present in the epidermis will replicate continuously and will
specific niches undergo differentiation to replace the lost
Explains why these organs (skin, intestines, liver) keratinocytes
have the capacity to regenerate
Tissue Proliferative Capacity
Labile Tissues
Proliferate throughout adult life or postnatal life
⭐Examples:
○ Bone marrow
RBCs die with a lifespan of about 3 months
Continuously produced to maintain adequate
Figure 4. Stem cell niches levels of RBCs and WBCs in the peripheral
A. Skin: Bulge stem cells beside hair follicles blood
B. Intestine: Stems cells lodged in the crypts Produce different lines of hematopoietic cells
C. Liver: Oval cells present in the canals of Hering
[Batch 2027]
○ Surface epithelium of the skin, GI tract, and
Mechanisms Regulating Cell Populations
urinary tract
Stem cells maintain the pool of regenerating cells [Batch
○ Cells of tissues lining cavities
2027]
“Why do we not run out of these stem cells?”
○ If we run out of stem cells, we lose the ability to Stable Tissues (Quiescent)
replace the tissues in the body Maintained in the G0 stage in the cell cycle
○ Some of the stem cells will replicate into baseline Low level of replication
cell population → proliferate and differentiate (ex: Can proliferate under stimuli (ex: injury)
into the stratum corneum layer of the skin) Examples: bone and liver
○ Some will replicate back into the stem cells to
maintain the stem cell pool
Stem cells regenerate themselves

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Figure 7. (L) Intramedullary cavity in the middle of the bone and a
normal lower cortex. Upper cortex presents with a callus after a
trauma/fracture. (R) Trichrome stain of cirrhotic liver.
○ Bone
Has a very low level of replication and very
slow turnover rate
Fracture due to blunt force trauma or vehicular Figure 8. ECM implications and Functions
accidents → osteocytes become active again to
help heal the fractured bone → callus [Batch 2027] Liver Regeneration in Post-Hepatectomy
Callus will form as a healing response to an Hepatocytes are composed of parenchymal cells and
injury/fracture rest on a scaffold of connective tissue on the ECM
○ Liver [Batch 2027]
Alcohol-induced liver injury, liver resection After a hepatectomy, the remaining liver parenchyma
(hepatectomy), or any injurious stimuli can has the ability to proliferate and regenerate from
induce liver regeneration existing progenitor cells
Two mechanisms are used to regenerate normal
Permanent Tissues liver tissue in post-hepatectomy patients: [Batch 2027]
Non-proliferative in postnatal life ○ Proliferation of remaining hepatocytes
Terminally differentiated ○ Liver regeneration from progenitor cells
Have a very limited capacity to repair themselves and
a very small stem cell pool → limited ability to
proliferate
Examples:
○ Neurons
○ Skeletal muscles
Satellite cells attached to the endomysial
sheath provide some regenerative capacity for
muscle [Robbins & Cotran, 10th ed., pg. 104]
○ Cardiac muscles
Px who experienced myocardial infarction (MI)
or part of the cardiac myocytes that undergo
necrosis → difficult to replace necrotic tissue
with viable myocytes due to permanence of Figure 9. Liver regeneration by hepatocyte proliferation with the aid
tissue and have very limited capacity to of growth factors.
proliferate in postnatal life [Batch 2027]
Restoration of normal tissue structure can occur only
if the residual tissue is structurally intact
ECM & Growth Factors (GF)
ECM is the architectural structure or scaffold of the
⭐ Even if the hepatocytes can regenerate, an intact
reticulin network or ECM is required for cells to
tissue [Batch 2027]
proliferate onto
Also have key roles in:
○ Cell proliferation by elaborating growth factors
○ Responding to injury and trauma
○ Proliferating blood vessels for the oxygen and
nutrient supply of cells
Growth factors are typically produced by cells
(macrophages and epithelial and stromal cells) near
the site of damage [Robbins & Cotran, 10th ed., pg. 104]
○ All growth factors activate signaling pathways
that stimulate DNA replication

Figure 10. Intact reticulin network in the liver parenchyma - Central
Vein in the middle portion surrounded by sinusoids

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The following conditions disrupt the normal reticulin TG Note: In Dr. Andal’s lecture, the steps in scar
network and produces scarring and fibrosis: formation are (1) Inflammation, (2) Granulation Tissue
○ Chronic tissue injury Formation, and (3) Connective Tissue Deposition.
○ Liver cirrhosis from alcohol injury (scarring) However, in Robbins & Cotran’s Pathologic Basis of
○ Hepatitis B or Hepatitis C infections Disease (10th edition), the steps in scar formation are (1)
Inflammation, (2) Cell Proliferation, (3) Granulation Tissue
Formation, and (4) Connective Tissue Deposition.

A. Steps in Scar Formation
1. Inflammation
Initiating Factor: tissue injury
Enables the migration of inflammatory cells to the
area of injury
Allows the formation of a temporary scab or plug
○ Recruits more inflammatory cells and sets the
stage for cell proliferation
Hemostatic Plug Formation[Robbins & Cotran, 10th ed., pg. 105]
○ Composed of platelets
○ Stops bleeding and provides a scaffold for the
Figure 11. Disorganized reticular network in a cirrhotic liver
deposition of fibrin
parenchyma with trichrome stain.
Figure 11 Chemotactic Agents[Robbins & Cotran, 10th ed., pg. 105]
○ Trichrome Stain: highlights the fibrous tissue in ○ Recruit neutrophils and monocytes over the next 6
blue to 48 hours
○ Red-Colored Tissue: normal hepatocytes ○ Eliminate offending agents and clear the debris
○ Blue-Stained Tissue: deposited fibrous tissue ○ Examples:
○ Cirrhotic liver is multinodular Breakdown products of complement activation
Due to nodules regenerating in the liver’s Chemokines released from activated platelets
fibrous tissue and destroyed ECM matrix Other mediators produced at the site of injury
○ As the injurious agents and necrotic cells are
Table 1. Intact vs disrupted reticulin network cleared, the inflammation resolves
DESCRIPTION
Hepatocytes can proliferate and TG Note: Dr. Andal refers to the second step as the
Intact Reticulin Formation of Granulation Tissue. However, his
regenerate to maintain liver
Network description of this step aligns with the text provided
architecture
Disrupted ECM under Cell Proliferation in Robbins & Cotran’s Pathologic
Generating hepatocytes can grow Basis of Disease (10th ed.). For this trans, we will
and Reticulin
but in a disarray combine and place both information provided under Cell
Network
Proliferation.
II. WOUND HEALING IN THE SKIN
2. Cell Proliferation
Takes up to 10 days
Several cell types proliferate and migrate to close the
wound
Allows for blood vessel to grow in the area of injury
and supply nutrients to the proliferating cells

Table 2. Cells in cell proliferation
CELL TYPES DESCRIPTION
Respond to locally produced
Figure 12. Steps in wound healing and scar formation in the skin. growth factors
Epithelial Cells
Migrate over the wound to cover it
Replacement of Injured Cells with Connective up
Tissue[Robbins & Cotran, 10th ed., pg. 105] Proliferate to form new blood
○ Occurs when repair by regeneration is not
possible
Endothelial Cells
and Pericytes ⭐️
vessels → angiogenesis
Pericytes: supporting cells that
hold new blood vessels together
○ Leads to:
Formation of a scar; or Proliferate and migrate into the
Combination of regeneration of some residual
cells and scar formation
⭐️ Fibroblasts site of injury
Lay down collagen fibers that form
Scar Formation: “patches” rather than restores the the scar
tissue[Robbins & Cotran, 10th ed., pg. 105]
Angiogenesis
Formation of new blood vessels

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Allows healing and repair in the injured tissues Migration and deposition of the
Involves signaling pathways, cell-cell interactions, basement membrane
Suppression of
ECM proteins, and tissue enzymes[Robbins & Cotran, 10th ed., pg. Once the new blood vessels are
endothelial
106] formed, a negative feedback
proliferation
Critical in the development of collateral circulations at mechanism suppresses the
sites of ischemia and tumor growth proliferation
○ Growing tumors will require new blood vessels to
allow cancer cells to grow Signaling Factors in Angiogenesis
Inhibiting the new blood vessels can Table 4. Signaling factors in angiogenesis
potentially help stop the growth of the tumor SIGNALING
DESCRIPTION
FACTORS
Steps in Angiogenesis Mainly VEGF-A [Robbins & Cotran, 10th ed., pg.
Vascular 106]
Endothelial Promotes vasodilation
Growth Factor ○ Nitric oxide (NO) production
(VEGF) Stimulates migration and
proliferation of endothelial cells
Mainly FGF-2[Robbins & Cotran, 10th ed., pg. 106]
Stimulates the proliferation of

Fibroblast
⭐️
endothelial cells
Promotes the migration of
macrophages and fibroblasts to the
Growth Factors
damaged area
(FGF)
Stimulates epithelial cell migration
to cover epidermal wounds
Fibroblasts: form fibrous tissue
○ Deposit collagen → fibrosis

Figure 13. Steps in angiogenesis

Table 3. Steps in angiogenesis
STEPS DESCRIPTION
In response to nitric oxide and
increased permeability induced by
the VEGFs
Vasodilation To allow for more blood flow and
the migration of inflammatory cells
Partly due to the inflammation that
occurs in the area [Batch 2027]
Pericytes separate from the Figure 14. Fibroblasts in varying appearance
abluminal surface
Breakdown of basement (A) Quiescent fibroblasts appear as spindle (more
Separation of
membrane by matrix elongated) or stellate-shaped cells (star-shaped)
Pericytes
metalloproteinases (MMPs) ○ Nucleus: has fine chromatin pattern and distinct
Allows the formation of a vessel nucleoli
sprout or “leading tip” cells (B) Active fibroblasts appear more plump [Batch 2027]
Endothelial cells from the existing (C) Fibroblasts may also appear as stellate- or
Migration of
blood vessel migrate to the new spindle-shaped on tissue culture
Endothelial Cells
blood vessels
Stimulated by the FGFs Platelet Participates in the stabilization of
Proliferation of
Behind the leading front (“tip”) of Derived Growth new blood vessels
Endothelial Cells
migrating cells Factor (PDGF) Recruits smooth muscle cells
The endothelial cells branch off
Remodeling into Specifically TGF-β
and meet each other
Capillary Tubes Supported by the ECM and
pericytes/smooth muscle cells
⭐️ Trans-
forming Growth
Suppresses endothelial proliferation
and migration
Enhances production of ECM
Recruitment of ○ Pericytes for small capillaries
Periendothelial Factor (TGF) proteins
○ Smooth muscle cells for larger
Cells Serves as the negative feedback
vessels
loop once the repair is done[Trans 2025]

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3. Formation of Granulation Tissue [Robbins & Cotran, 10th ed., pg. 105] ⭐️ TGF-β
Granulation Tissue Formation From Dr. Andal
○ Migration and proliferation of fibroblasts “The cytokine that I want you to remember, and this
○ Deposition of loose connective tissue will most likely come out in the exam, is TGF-β.”
○ Vessels and interspersed mononuclear leukocytes
Histologic Appearance: One of the most important cytokines for the synthesis
○ Proliferation of fibroblasts and new thin-walled, and deposition of connective tissue proteins
delicate capillaries in a loose ECM Produced by macrophages and other cells of the
○ Often mixed with inflammatory cells (mainly granulation tissue
macrophages) Functions:
Granulation tissue progressively fills the site of injury ○ Stimulates fibroblast migration and proliferation
○ Amount of tissue formed depends on the size of Elaboration of TGF-β in the area where scar
the tissue defect and intensity of inflammation tissue deposition is needed because fibroblasts
and connective tissue are wanted in that area
○ Increases synthesis of collagen and fibronectin
○ Decreases degradation of ECM by inhibiting
metalloproteinases
Part of the feedback loop and regulatory
processes: the presence of metalloproteinases
that degrade the ECM.
At the early stages: decrease of ECM
degradation is wanted
At later stages: promotion of ECM degradation
is wanted for remodeling scar tissue area

Figure 15. Chronic inflammation and granulation tissue

Figure 15
○ On the surface: fibrin and inflammatory cells
○ Deeper layers: new blood vessels Figure 16. Fibrosis in granulation tissue. (A) H and E section: cells
Clear spaces are the lumen of the vessels are stained pink or purple (B) Trichrome stain highlights
collagen/fibrosis as blue-stained tissues.
○ White areas: loose connective tissue
Figure 16
From 2026 Trans: ○ A: An area of young or early stages of granulation
New blood vessels = key feature of granulation tissue tissue formation
Macrophages = key feature in the latter phase of healing Areas full of blood cells: Blood vessels
More inflammatory cells found in areas of infection Small dots: inflammatory cells
Appearance of granulation tissue varies depending on
Blue squiggly lines: areas of collagen
phase of granulation tissue formation
○ Acute phase = more loose, and less fibrosis deposition
○ Latter phase = less blood vessels, more fibrosis Only small amount of fibrous tissue in the
early stages of collagen/fibrous tissue
deposition
4. Deposition of Connective Tissue ○ B: More blue due to larger amount of fibrous
Steps in deposition of connective tissue: tissue deposited in the scar tissue
○ Migration and proliferation of fibroblasts into the
site of injury From Dr. Andal (If an exam question were to be asked:)
○ Deposition of ECM proteins “Which of these two micrographs represents later
The fibroblasts migrate into the base of the injured phases of scar tissue deposition?”
area and deposit ECM proteins (e.g. fibrous tissue) ○ Answer: the one on the right.
and other matrix proteins. More blue = more fibrosis in the tissue
○ Results in the formation of a collagenous scar Has a lot less vessels: because the tissue is
○ Collagen: a fibrous tissue being remodeled, as part of the reparative
Deposition of collagen is from the fibroblasts that process
have migrated from onto that area. Less blood vessel formation and less
○ Critical for the development of strength in a inflammation, but more collagen deposition,
healing wound site [Robbins & Cotran, 10th ed., pg. 107] in the latter phases
“Which stain is used to highlight fibrous tissue?”
○ Answer: Trichrome stain

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Fibroblasts-Myofibroblasts
FIBROBLASTS
Elaborate and increase ECM synthesis
Acquire features of smooth muscle cells (Actin
filament)
Marked ability to differentiate and form
myofibroblasts.

Figure 18. Healing of skin wounds by first intention (L) and second
intention (R). In the latter, note the large amount of granulation
Figure 17. Two-stage model of myofibroblast differentiation. Under tissue and wound contraction
mechanical stress, fibroblasts will differentiate into myofibroblast
Healing by First Intention
MYOFIBROBLASTS
Also referred to as: epithelial generation, primary
Myofibroblast= fibroblast with actin filament [Batch 2027]
union.
Continue to Scar contraction
The principal mechanism of repairing an injury that
○ Because ends of wound need to be apposed
involves only the epithelial layer
together to heal
○ Example: surgical scars, clean and small
○ Ex. Wound with large surgical defects. Scar tissue
lacerations
will be needed to contract the edges of the
Repair has three connected processes:
surgical scar to go near each other[Batch 2027]
○ Inflammation
Remodeling of Connective Tissue ○ Proliferation
After deposition, the connective tissue in the scar ○ Maturation
continues to be modified and remodeled [Batch 2027] Wounding rapidly activates the coagulase pathway.
Negative feedback loop is needed once scar As a result, there is formation of blood clots on the
formation is done and healing is in the latter phases. wound surface. [Robbins & Cotran, 10th ed., pg. 108]
The collagen and fibrous tissue that have been ○ Clot:
deposited in the area need to be degraded for Stops the bleeding
remodeling. Supports migrating cells, which are attracted
○ This will allow the reconstitution of the normal by growth factors, cytokines and chemokines
cells that were present before the injury occurred. released in the area.
Greater amount of the following enzymes will help
remodel the collagen scar, prevent excess collagen TG Note: The contents of Tables 5 and 6 were not
deposition or excessive fibrosis, and help the area go discussed to us by Doc. However, they were included
back to pre-injury state [Batch 2027] because Doc Andal seemed to have tackled a few of the
○ Matrix metalloproteinases (MMPs) specified events in his discussion from last year.
○ Collagenases
○ Tissue inhibitors of metalloproteinases (TIMPs)
Table 5. Events in healing by first intention [Robbins and Cotran, p. 108; Trans 2027]
III. CLINICAL CONTEXT Timeline Events
A. Healing of Skin Wounds Sutured wounds are approximated by the
There are two types of healing in the context of skin sutures
wounds: Scab formation
○ Healing by First intention/primary union Hemostasis occurs immediately
○ Healing by Second Intention/secondary union Neutrophils, inflammatory cells, fibroblasts
are recruited to the fibrin clot forming
24 Hours
granulation tissue
After
Basal cells at the edge of the incision begin
Surgery
to show mitotic activity
Within 24–48 hours, epithelial cells from
both edges have begun to migrate and
proliferate along the dermis, yielding a thin
but continuous epithelial layer that closes
the wound.

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Variable amount of fibrosis Accumulation of ECM
Less amount of new blood vessel formation Through myofibroblastic action, wound contraction
Wound is starting to be covered up by new helps to close the wound.
skin cells ○ Decreases the gap between its dermal edges
Still some scab formation at the top ○ Reduces the wound surface area
Macrophages in the area ○ Important feature in healing by secondary union
Neutrophils have been largely ○ Wound contraction involves a network of
replaced by macrophages. myofibroblasts, modified fibroblasts which have
○ The macrophages clear contractile properties
extracellular debris, fibrin, Table 6. Events in healing by second intention [Robbins and Cotran, p. 109]
and other foreign Timeline Events
Day 3
material; promote 24 Hours Provisional matrix containing fibrin,
angiogenesis; and ECM After plasma, fibronectin, and type III
deposition. Surgery collagen is formed.
3–7 Days Granulation tissue progressively Matrix becomes mostly composed of
invades the incision space. type I collagen.
Neovascularization reaches its Original granulation tissue scaffold is
peak as granulation tissue fills 2 Weeks converted into a pale, avascular scar.
the incisional space. Dermal appendages that have been
The new vessels are leaky, destroyed in the line of the incision are
allowing the passage of plasma permanently lost.
proteins and fluid into the By the Scar is made up of acellular connective
Day 5 extravascular space. End of the tissue devoid of inflammatory infiltrate.
○ New granulation tissue is 1st Month ○ Covered by intact epidermis
often edematous.
Large skin defects may be reduced to
Fibroblasts progressively Within 6
5% to 10% of their original size by
migrate into the granulation Weeks
wound contraction of myofibroblasts.
tissue, where they proliferate
and lay down collagen and ECM.
B. Surgical Wound Strength
Skin is fully re-epithelialized When doing surgery on a patient, a small surgical
Collagen deposition is remodeled incision is done. After the surgery, this incision is
Structural integrity is back to normal sutured up.
Continued collagen Healing of the incision is facilitated by sutures.
accumulation and fibroblast In the area where the wound occurs, collagen
2nd proliferation. synthesis should happen.
Week Leukocyte infiltrate, edema, and ○ Deposition of fibrous collagen promotes and
increased vascularity are imparts tensile strength to the wound.
Weeks substantially diminished. Sutured wounds are 70% of normal skin strength by
Scar comprises a cellular ~3 months
connective tissue.
○ Devoid of inflammatory IV. FACTORS THAT INFLUENCE TISSUE
End of
the First
cells REPAIR
○ Covered by a normal
Month TG Note: Some of the descriptions as listed on the succeeding
epidermis.
The wound’s tensile strength table were lifted from Robbins and Cotran (10th ed., p. 108)
increases with time. since Doc did not specify on most of them.

Healing by Second Intention Tissue repair can be influenced by several factors,
Also referred to as secondary union thereby altering the reparative process. There are
Form that is delayed in one way or another systemic and local, as well as extrinsic or local
○ E.g., When you want to delay healing variables, that modify healing.
The type of healing of skin wounds will also
determine the types and different physio-changes in
Table 7. ⭐ Factors that influence tissue repair
Factors Description
the patient. Clinically one of the most important
Happens when cell or tissue loss is more extensive causes of delayed healing
Inflammatory reaction is more intense Promotes continuous inflammation in a
○ Large tissue defects have more necrotic debris, specific area
exudate, and fibrin that must be removed → large ○ E.g., A surgeon’s failure to use
defects have a greater potential for secondary, Infection antiseptic systems allow
inflammation-mediated injury microbes to come in → infection
More granulation tissue development → affecting tissue repair →
○ To fill in a bigger gap due to the larger area of delays healing
deficit Potentially increases the local tissue
○ Greater volume of granulation tissue → greater injury
mass of scar tissue → large scar formation

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Metabolic disease that compromises Once fibrosis is organized in body
tissue repair. cavities, function will be affected.
Diabetes
One of the most important systemic ○ E.g., Pneumonia
causes of abnormal wound healing Infection can spill over the
Profound effects on repair pleural cavities organizing
Nutritional Protein and vitamin C deficiency: fibrosis → affect the patient’s
status ○ Inhibit collagen synthesis breathing
○ Retard healing
Have antiinflammatory effects V. ABNORMALITIES IN TISSUE REPAIR
Administration may result in weakness A. Chronic Wounds
of the scar due to:
○ Inhibition of TGF-β production
○ Diminished fibrosis
Glucocorti- However, these above-mentioned
coids effects of glucocorticoids are desirable
(steroids) in certain cases.
○ E.g., Corneal infections -
glucocorticoids + antibiotics are
prescribed to reduce the
likelihood of opacity that may Figure 19. Chronic wounds illustrating defects in wound healing (A)
Venous leg ulcer (B) Arterial ulcer (C) Diabetic ulcer, and (D)
result from scarring
Pressure sore
Eg., Increased local pressure or torsion
May cause wounds to pull apart or
dehisce
E.g., Fractured ends of the bone
Mechanical
continues to move
factors
○ Callus, reparative tissue will not
set in
○ Important to immobilize for a
while Figure 20. L: Ulcer crater taken from site of venous leg ulcer
Impairs healing due to its effect on R: Middle part of the ulcer zoomed in
angiogenesis
○ Poor blood supply → delay Venous Leg Ulcers
tissue repair Common in elderly with chronic venous hypertension
Poor May be due to: Caused by severe varicose veins or congestive heart
perfusion ○ Peripheral vascular disease failure
○ Arteriosclerosis Commonly accompanied by chronic inflammation and
○ Diabetes deposits of hemosiderin (iron pigment) from red cell
○ Obstructed venous drainage breakdown
(e.g., in varicose veins) Poor venous circulation can affect wound healing due
May result in inflammation, delaying to poor oxygen delivery to the site of ulcer
wound healing Fig. 20 (L)
Foreign ○ The edges of the ulcer (arrows) will show more
Fragments of steel, glass, or bone
bodies
impede healing by perpetuating
chronic inflammation Fig. 20 (R) components
○ Blood vessel formation
⭐
hanging stratified squamous epithelium of the skin

Stable and labile cells → complete
Type and ○ White Areas: edema with variable amounts of
restoration
extent of inflammatory cell
Permanent cells → scarring, loss of
tissue injury ○ Elongated spindle cells
function
Inflammation arising in tissue spaces Arterial Ulcers
develops extensive exudates Develop in individuals with atherosclerosis of the
Repair may occur by digestion of peripheral arteries especially associated with
exudate. diabetes
○ This is initiated by proteolytic Ischemia results in atrophy and necrosis of the skin
enzymes of leukocytes + and underlying tissue
resorption of the liquefied Lesions are painful
Location of
exudate → resolution
the injury
In the absence of cellular necrosis,
normal tissue architecture is
⭐Diabetic Ulcers
May also be referred as diabetic foot
generally restored Affects the lower extremities, particularly the feet
In the case of larger accumulations, Presence of tissue necrosis and failure to heal as a
granulation tissue grows into the result of vascular disease
exudate → formation of a fibrous
scar → organization

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Histologically characterized by:
○ Epithelial ulceration (Fig. 20L)
⭐ Keloid
Results from the inability to remodel the fibrous
○ Extensive granulation tissue in the dermis (bed of tissue.
the ulcer) which is formed by: Scar tissue grows beyond the boundaries of the
New blood vessels original wound and does not regress.
Loose edematous connective tissue Common in African Americans and people with
↪ White spaces in between new blood darker skin color, can also occur in some Asians.
vessels correspond to the presence of Keloid will form exuberant fibrous tissue covered by
edema fluid hyperpigmented skin
Inflammation Histologically, fibrous tissue will appear differently
based on the staining:
Pressure Sores
○ H&E stain: pink
Happens when the patient lies in a particular position
○ Trichrome stain: blue
for a long amount of time
(Figure 21C) Stratified squamous epithelium is on top
○ E.g., Bedridden patients
(black arrow), while bundles of dense collagen
Areas of skin ulceration and necrosis of underlying
bands correspond to fibrous tissue that was not
tissues caused by prolonged compression of tissue
remodeled (red arrow)
against a bone
○ Important to remove and remodel scar tissue to
Lesions are caused by mechanical pressure in a
prevent this.
specific area and local ischemia.
○ Pressure sores can be produced by cutting off the
Under the microscope, hypertrophic scars and keloids
blood supply
can appear the same since they are both characterized by
B. Wound Dehiscence collagen bundles. However, in hypertrophic scars,
Happens when a surgical incision reopens internally collagen deposition does not grow outside the boundary
or externally of that tissue. In keloid, collagen production is abundant,
Risk factors: which is why it overhangs the injured area.
○ Obesity
○ Malnutrition SUMMARY/ KEY POINTS FROM DR. ANDAL
○ Infections
○ Vascular insufficiency STEP DESCRIPTION, KEY POINTS
The suture strength holding the abdominal wound Inflammatory cells: chemokines,
together can be affected by increased pressure neutrophils, and macrophages to
Inflammation
○ Vomiting, coughing, and other physical factors remove the debris and microbes
present in the area of injury
C. Excessive Scar Tissue Deposition Granulation tissue Presence of new blood vessels and
formation the process of angiogenesis
Fibrous collagen deposited by
Connective tissue fibroblasts
deposition Scar contraction due to
myofibroblasts

DETERMINANT DESCRIPTION
E.g. whether the injury is a small
Nature of the injury incision or laceration or large
Figure 21. (A) Hypertrophic scar (B) Keloid (C) Microscopic image of
abrasion
a keloid

⭐
Hypertrophic Scars Cell proliferation
Whether there are stem cells
present in the tissue that will allow
Scar deposition (stem cell function) for faster regeneration of the tissues
Normally: in the area
○ Scar formation occurs → once scar is deposited, E.g. As seen in the skin and liver
there is a need to remodel that scar → remove Once the ECM is disrupted in a
deposited connective tissue to allow cells and very significant fashion, there can
tissues (that were present before the injury) to Integrity of the
be scar formation, but the ability
replace the scar tissue ECM (scar
to remodel and degrade the scar
Hypertrophic scar: formation,
is also a key factor in how the
○ Results from the inability to remodel the fibrous remodeling)
patient heals
tissue ○ E.g. from burns or large
This pathology is also found in keloids. abrasions
○ Excessive scar deposition
Accumulation of excessive amounts of collagen Main Components of Connective Tissue Repair
Often grow rapidly and has abundant myofibroblasts Angiogenesis
Tend to regress over several months Fibroblast migration and proliferation
Generally develop after thermal or traumatic injury Collagen synthesis
involving deep layers of the dermis Connective tissue remodeling
Fibrosis formed is within the boundaries of the wound

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Repair by Connective Tissue Deposition
5. The histological appearance of a tissue you’re
Granulation formation examining presents with fibroblasts, new
Fibrosis - remodeling thin-walled capillaries, a loose ECM, and
Multiple factors affecting healing (Refer to Table 7) macrophages. Which of the following is FALSE?
Infection A. The tissue is in the stage of granulation tissue
Diabetes formation
Nutritional status B. The next step involves recruiting neutrophils
Glucocorticoids (steroids) and the formation of a platelet plug
Mechanical factors C. The macrophages indicate that the tissue is in
Poor perfusion the latter phase of healing
Foreign bodies D. The fibroblasts deposit collagen, leading to the
Type and extent of tissue injury fibrosis of the tissue
Location of the injury
Deposition of Connective Tissue
REFERENCES
6. The following are all functions of TGF-β except…
Jose Jasper L. Andal MD. Notes from Tissue Renewal
A. Increases synthesis of collagen and fibronectin
and Repair
B. Stimulates migration and proliferation of
BOOKS endothelial cells
Kumar, V., Abbas, A. and Aster, J. (2020) Robbins and C. Decreases degradation of ECM
Cotran Pathologic Basis of Diseases. 10th Edition, D. Stimulates fibroblast migration and proliferation
Elsevier
7. In the early part of scar tissue deposition, ECM
REVIEW QUESTIONS degradation is promoted. This is then followed by
scar contraction by myofibroblasts.
Mechanisms of Tissue Repair A. Only the first statement is true.
B. Only the second statement is true.
1. What are the two main mechanisms of tissue repair? C. Both statements are true.
A. Regeneration and inflammation D. Both statements are false.
B. Regeneration and scar formation
C. Scar formation and cell death Healing of Skin Wounds
D. D) Inflammation and fibrosis
8. What is the first step in the repair process of healing
Tissue Proliferative Capacity by first intention?
A. Maturation
2. Which of the following is an example of a labile B. Inflammation
tissue? C. Proliferation
A. Bone D. Remodeling
B. Liver
C. Neuron Factors that Influence Tissue Repair
D. Skin Epithelium
9. Which of the following statements is true in relation
ECM and Growth Factors to the factors that influence tissue repair?
A. Deficiency in protein and vitamin D inhibit
3. Which of the following statements about the ECM is collagen synthesis, thereby retarding the healing
correct? process.
A. The ECM has no role in cell proliferation B. Permanent cells will result in complete
B. The ECM provides structural support but does restoration, whereas stable and labile cells will
not influence growth factors result in loss of function.
C. The ECM elaborates growth factors that are C. Diabetes may impede healing due to poor blood
crucial for cell proliferation supply.
D. The ECM is not required for liver regeneration D. In healing, glucocorticoids should always be
avoided due to inhibition of TGF-β production
Steps in Scar Formation and diminished fibrosis.

4. Which of the following is NOT a function of Abnormalities in Tissue Repair
fibroblast growth factors?
A. Stimulates the proliferation of endothelial cells 10. Keloid and arterial ulcers appear similar
B. Promotes the migration of macrophages and histologically because both have collagen bundles. In
fibroblasts to the damaged area terms of excessive scar tissue deposition,
C. Promotes the breakdown of the basement hypertrophic scars usually regress because they
membrane grow beyond the boundary of the wound.
D. Stimulates epithelial cell migration to cover A. Only the first statement is true.
epidermal wounds B. Only the second statement is true.

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C. Both statements are true. 8. B - Recall
D. Both statements are false. 9. C-
Protein deficiency and vitamin C deficiency
ANSWERS/RATIONALE
Stable and labile cells → complete restoration.
Permanent cells → scarring, loss of function.
1. B - Recall
2. D - Recall Effects of glucocorticoids are desirable in certain
3. C - Recall cases.
4. C - Recall. The breakdown of the basement E.g., Corneal infections
membrane is stimulated by matrix 10. D -
metalloproteinases Hypertrophic scars and keloids can appear the
5. B - Recruiting neutrophils and the formation of a same since they are both characterized by
platelet plug occurs in the first step, prior to the collagen bundles
formation of the granulation tissue.
11.

Fibrosis formed is within the boundaries of the
6. B - Recall wound
7. D - In the early stage of scar tissue deposition,
decrease of ECM degradation is promoted. ECM
degradation occurs in the later stage of scar
tissue deposition

SUMMARY

2 PROCESSES OF TISSUE REPAIR
Tissues can replace damaged components and essentially return to normal state
Repairs through:
Regeneration
○ Proliferation of differentiated cells
○ Differentiation and proliferation of stem cells
Injured tissue is incapable of regeneration
Supporting structures are too severely damaged and cannot support regeneration
Scar Formation Repairs through:
○ Fibrosis
○ Collagen deposition

DETERMINANTS OF TISSUE REPAIR
Nature of the injury
Give rise to various differentiated tissues
In vivo: different cell lines mature into every possible tissue in an
Embryonic Stem cells infant
Cell proliferation In vitro: can be cultured and given growth factors to become
different cell lines
Only have the capacity to replace damaged cells and maintain cell
Adult Stem cells
populations within the tissues where they reside
ECM is the architectural structure or scaffold of the tissue
Also have key roles in:
○ Cell proliferation by elaborating growth factors
ECM and Growth Factors
○ Responding to injury and trauma
○ Proliferating blood vessels for the oxygen and nutrient
supply of cells

STEPS IN SCAR FORMATION
Tissue injury acts as the initiating factor
Platelet plug-hemostasis
○ Plugs blood vessels and lost tissue to prevent further blood loss and promote hemostasis
Inflammation Chemokines attract neutrophils
Inflammation removes microbes, debris
○ Removed by macrophages and neutrophils
○ Inflammation resolved when cleared
Occurs after inflammation is resolved
Cells proliferate and migrate to close the clean wound
○ Epithelial cells
Cell proliferation
respond to locally produced growth factors and migrate over the wound to cover it up
○ Pericytes and Endothelial Cells
proliferate to form new blood vessels, a process known as Angiogenesis.

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○ Fibroblasts
lays down collagen fibers that form the scar
Granulation Tissue Formation
Formation of ○ Migration and proliferation of fibroblasts
Granulation Tissue ○ Deposition of loose connective tissue
○ Vessels and interspersed mononuclear leukocytes
Steps in deposition of connective tissue:
○ Migration and proliferation of fibroblasts into the site of injury
○ Deposition of ECM proteins
TGF-β
○ One of the most important cytokines for the synthesis and deposition of connective tissue
proteins
○ Stimulates fibroblast migration and proliferation
○ Increases synthesis of collagen and fibronectin
○ Decreases degradation of ECM by inhibiting metalloproteinases
Fibroblasts
Deposition of ○ Elaborate and increase ECM synthesis
Connective Tissue ○ Acquire features of smooth muscle cells (Actin filament)
○ Marked ability to differentiate and form myofibroblasts.
Myofibroblasts
○ Myofibroblast= fibroblast with actin filament
○ Continue to Scar contraction
Remodeling of Connective Tissue
amount of the following enzymes will help remodel the collagen scar, prevent excess collagen
deposition or excessive fibrosis and help the area of back to pre-injury state:
○ Matrix metalloproteinases (MMPs)
○ Collagenases
○ Tissue inhibitors of metalloproteinases (TIMPs)

CLINICAL CONTEXT
HEALING OF SKIN WOUNDS
Healing by First Intetion Healing by Second Intention
When the injury involves only the epithelial layer, the principal
When cell or tissue loss is more extensive
mechanism of repair is epithelial regeneration or primary union
Also called secondary union
Repair consists of three connected processes:
Inflammatory reaction is more intense
○ Inflammation
Development of granulation tissue
○ Proliferation
Accumulation of ECM and formation of a large scar
○ Maturation
Would contraction by the action of myofibroblasts
Surgical wound strength
70% of normal skin strength
Collagen synthesis responsible for producing tensile strength to help close the wound
Wound strength is 70 - 80% normal by 3 months

FACTORS INFLUENCING TISSUE REPAIR
Clinically one of the most important causes of delayed healing
Promotes continuous inflammation in a specific area
Infection ○ E.g., A surgeon’s failure to use antiseptic systems allow microbes to come in → infection →
affecting tissue repair → delays healing
Potentially increases the local tissue injury
Metabolic disease that compromises tissue repair.
Diabetes
One of the most important systemic causes of abnormal wound healing.
Profound effects on repair
Protein deficiency and vitamin C deficiency:
Nutritional status
○ Inhibit collagen synthesis
○ Retard healing
Have antiinflammatory effects
Administration may result in weakness of the scar due to:
○ Inhibition of TGF-β production
Glucocorticoids
○ Diminished fibrosis
(steroids)
However, these above-mentioned effects of glucocorticoids are desirable in certain cases.
○ E.g., Corneal infections - glucocorticoids + antibiotics are prescribed to reduce the likelihood of
opacity that may result from scarring

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Example includes increased local pressure or torsion
May cause wounds to pull apart or dehisce
Mechanical factors E.g., Fractured ends of the bone continues to move
○ Callus, reparative tissue will not set in
○ Important to immobilize for a while.
Impairs healing due to its effect on angiogenesis
○ Poor blood supply → delay tissue repair
May be due to:
Poor perfusion ○ Peripheral vascular disease
○ Arteriosclerosis
○ Diabetes
○ Obstructed venous drainage (e.g., in varicose veins)
May result in inflammation, delaying wound healing.
Foreign bodies
Fragments of steel, glass, or bone impede healing by perpetuating chronic inflammation.
Type and extent of Stable and labile cells → complete restoration.
tissue injury Permanent cells → scarring, loss of function.
Inflammation arising in tissue spaces develops extensive exudates.
Repair may occur by digestion of exudate.
○ This is initiated by proteolytic enzymes of leukocytes + resorption of the liquefied exudate →
resolution
In the absence of cellular necrosis, normal tissue architecture is generally restored
Location of the
In the case of larger accumulations, granulation tissue grows into the exudate → formation of a
injury
fibrous scar → organization
Once fibrosis is organized in body cavities, function will be affected.
○ E.g., Pneumonia
Infection can spill over the pleural cavities organizing fibrosis → affect the patient’s
breathing.

ABNORMALITIES IN TISSUE REPAIR
Venous Leg Ulcer
Common in elderly with chronic venous hypertension
Caused by severe varicose veins or congestive heart failure

Arterial Ulcers
Develop in individuals with atherosclerosis of the peripheral arteries especially associated with
diabetes
Ischemia results in atrophy and necrosis of the skin and underlying tissue
Chronic wounds
Diabetic ulcers
Affects the lower extremities (particularly the feet)
Presence of tissue necrosis and failure to heal as a result of vascular disease

Pressure sores
Common in patients who are bedridden for a long time
Areas of skin ulceration and necrosis of underlying tissues caused by prolonged compression of
tissue against a bone
Lesions are caused by mechanical pressure and local ischemia

When a surgical incision reopens internally or externally
Wound Dehiscence Risk factors: obesity, malnutrition, infections, and vascular insufficiency
The suture strength holding the abdominal wound together can be affected by increased pressure

Hypertrophic scars
Accumulation of excessive amounts of collagen
Often grow rapidly and has abundant myofibroblasts
Excessive Scar Fibrosis formed is within the boundaries of the wound
Tissue Deposition
Keloid
Scar tissue grows beyond the boundaries of the original wound and does not regress
Keloid will form exuberant fibrous tissue covered by hyperpigmented skin

FREEDOM WALL

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