Cell injury, necrosis and apoptosis.
Wound healing
September 27, 2011

Cell survival and death
ÚThe balance between cell survival and death is under tight genetic control. A multiplicity of
extracellular signals and intracellular mediators is involved in maintaining this balance.
ÚWhen the cell is exposed to physical, biochemical or biological injury, or deprived of necessary
substances, it activates a series of stress-response genes.
ÚWith minimal insults, the cell may recover.
ÚWith greater insults, single cell death, or , results; the cell dies and is recycled to its
neighbours.
ÚIf the insult overwhelms a large number of cells then necrosis ensues, with an accompanying
inflammatory response.
ÚDysregulation of the controlling  of this system results in disease.
ÚDeficient  is associated with cancer, auto-immunity and viral infections.
ÚExcessive  is associated with ischaemic heart disease, stroke, neurodegenerative disease, sepsis
and multiple organ dysfunction syndrome. There are myriad therapeutic options unfolding as
understanding is gained of  and its control.

Cell death
ÚCell death, a tightly controlled, finely orchestrated event, may be described either as  or
nonapoptotic cell death, traditionally called 'necrosis'.
ÚApoptosis is a process of cell suicide, the  of which are encoded in the chromosomes of all
nucleated cells. Physiological cell death that removes unwanted cells plays an important role in
development, tissue homeostasis and defence against viral infection and mutation.
ÚApoptosis is regulated by complex molecular signalling systems. Tissue ischaemia and reperfusion
activate these molecular systems, which therefore represent a therapeutic target for novel
treatment to preserve cellular integrity in critical organs such as the brain and heart.
ÚApoptotic cells undergo orderly, energy-dependent enzymatic breakdown into characteristic
molecular fragments, deoxyribonucleic acid (DNA), lipids and other macromolecules, which are
packaged into small vesicles that may be phagocytosed and reused. The cells involute and die with
minimal harm to nearby cells.
ÚIn contrast 'necrotic' cell death is characterised by inflammation and widespread damage.

Mechanisms of cell death
ÚFollowing an appropriate stimulus, the first stage or 'decision phase' of  is the genetic control
point of cell death. This is followed by the second stage or 'execution' phase, which is
responsible for the morphological changes of cells.
ÚThere are four main groups of stimuli for apoptosis.
ÚThe first group of stimuli causes DNA damage and include ionising radiation and alkylating
anticancer drugs.
ÚThe second group induces  via receptor , either by receptor activation mediated by glucocorticoids
(acting on the thymus), tumour necrosis factor-α (TNF-α), or by withdrawal of growth factors (nerve
growth factor and interleukin (IL)-3).
ÚThe third group comprises biochemical agents that enhance the downstream components of the
apoptotic pathway and includes phosphatases and kinase inhibitors (e.g. calphostin C,
staurosporine).
ÚThe fourth group comprises agents that cause direct cell membrane damage and includes heat,
ultraviolet light and oxidising agents (superoxide anion, hydrogen peroxide). Excessive production
of reactive oxygen species (ROS), such as superoxide, hydrogen peroxide and the hydroxyl radicals,
produces free radicals that damage lipid membranes, proteins, nucleic acids and extracellular
matrix glycosaminoglycans. Many of these stimuli cause necrosis in larger doses.
ÚInjury to cell membranes induces  by activating acid sphingomyelinase that generates the second
messenger ceramide from membrane lipids.

Cell death
Úis clearly an important factor in development, homeostasis, pathology and in aging, but medical
efforts based on controlling cell death have not become major aspects of medicine. Most effort has
focused on the machinery of cell death, or the proximate effectors of apoptosis and their closely
associated and interacting proteins. But cells have many options other than apoptosis. These
include autophagy, necrosis, atrophy and stepwise or other alternate means of self-disassembly.
ÚThe response of a cell to a noxious or otherwise intimidating signal will depend heavily on the
history, lineage and current status of the cell.
ÚMany metabolic and other processes adjust the sensitivity of cells to signals, and viruses
aggressively attempt to regulate the death of their host cells.
ÚAnother complicating factor is that many death-associated proteins may have functions totally
unrelated to their role in cell death, generating the possibility of undesirable side effects if
one interferes with them.

Necrosis or apoptosis?
Ú
ÚCells usually die either by necrosis or apoptosis. The characteristics of apoptotic death are more
clearly understood when compared to the characteristics of necrotic death.
ÚNecrosis is a pathological death of cells resulting from irreversible damage and is a term
commonly used in pulpal diagnosis.
ÚThe earliest irreversible changes are mitochondrial, consisting of swelling and granular calcium
deposits. After such changes, the outlines of individual cells are indistinct and affected cells
may become merged, sometimes forming a focus of coarsely granular, amorphous or hyaline material.
ÚThese features include
ocell swelling
omembrane lysis
oinflammatory response

Difference between apoptosis and necrosis
Apoptosis
Necrosis
Physiological or pathological
Always pathological
Asynchronous process in single cells
Occurs synchronously in multiple cells
Genetically controlled
Caused by overwhelming noxious stimuli
Late loss of membrane integrity
Early loss of membrane integrity
Cell shrinkage
Generalised cell and nucleus swelling
Condensation of nuclear contents
('ladder' formation of chromatin)
Nuclear chromatin disintegration
No inflammatory reaction
Inflammatory reaction

Necrosis
Úhas been defined as a type of cell death that lacks the features of apoptosis and autophagy, and
is usually considered to be uncontrolled.
ÚRecent research suggests, however, that its occurrence and course might be tightly regulated.
After signaling- or damage-induced lesions, necrosis can include signs of controlled processes such
Úas mitochondrial dysfunction,
Úenhanced generation of reactive oxygen species,
ÚATP depletion,
Úproteolysis by calpains and cathepsins,
Úearly plasma membrane rupture.
ÚIn addition, the inhibition of specific proteins involved in regulating apoptosis or autophagy can
change the type of cell death to necrosis. Because necrosis is prominent in ischemia, trauma and
possibly some forms of neurodegeneration, further biochemical comprehension and molecular
definition of this process could have important clinical implications.

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Apoptosis-description I
Ú is a fundamental process that is essential for development and homeostasis, but also contributes
to diverse pathologic processes, ranging from cancer and atherosclerosis to rheumatic and
neurodegenerative diseases.
ÚThe endothelium senses and transduces signals between blood and tissue, orchestrates the
trafficking of hematopoietic cells, maintains a non-thrombogenic surface permitting the flow of
blood, and initiates and amplifies the inflammatory response. Situated at the interface between
blood and tissue, the endothelium is exposed to stimuli with the potential to promote or prevent.
ÚPhysiological endothelial function involves a balance between pro- and anti-apoptotic signals, and
perturbation of this balance may contribute to the pathogenesis of diverse vascular diseases.

Apoptosis-description II
ÚIn this particular mechanism, and there are many, procaspase (inactive form) is activated to the
protease caspase. An amplification cascade then ensues with caspases activating other caspases,
eventually cleaving the host cell by acting on a variety of cell structures such as the nuclear
membrane. The cell shrinks in the process and there is a loss of cell–cell junctions resulting in
detachment from adjacent cells. The chromatin condenses, the cytoplasm 'blebs' (forms so-called
'pseudopods') and the cell breaks up into fragments known as 'apoptotic bodies'. Indirectly
activated endonucleases lead to breakdown of the DNA into multiples of 180–200 base pair fragments
Finally, either macrophages or adjacent cells phagocytose the apoptotic bodies.

Apoptosis-description III
ÚThe entire process of  takes about 1 h from initiation The initiating triggers are many and
varied, and are grouped broadly as physiological or nonphysiological.
ÚThese include, but are not limited to, the following: Fas ligands (Fas), tumour necrosis factor
(TNF), nerve growth factor (NGF), nitric oxide (NO), lipopolysaccharide (LPS), host immune
reactions, kinins and glucocorticoids.
ÚThe best characterised apoptotic trigger is the Fas ligand, a member of the TNF super-family. The
Fas receptor is a cell surface glycoprotein that mediates apoptotic signals from the cell surface
into the cytoplasm. When the Fas ligand binds to the Fas receptor on the cell membrane, the newly
formed Fas complex is allowed to associate with intracellular proteins. The morphological changes
of specific intracellular proteins induced by this complex result in the activation of other
substances such as IL-1β converting enzyme (ICE).

Definition
ÚApoptosis is now recognized as an important process in different biological systems, including
embryonic development, cell turnover, and immune response against tumorigenic or virus-infected
cells.
ÚUnder either physiological or pathological conditions, apoptosis is mostly driven by interactions
among several families of protein,i.e. caspases, Bcl-2 family proteins, and inhibitor of apoptosis
proteins (IAP). Other proteases such as granzyme B, calpain and cathepsin have also been
demonstrated to play a vital role in apoptosis occurring under certain physiological states.

Decision phase (genetic control)
Úis controlled genetically and two genes, Bcl-2 and p53 are important. The first, Bcl-2, is a
family of genes that regulates apoptosis; found on the mitochondrial membrane, endoplasmic
reticulum it may control calcium channels. It is now recognised that there is a family of mammalian
proteins similar to Bcl-2 that promotes or inhibits apoptosis. Proteins such as Bcl-2 and Bcl-xL
prevent , whereas Bcl-2 associated x proteins (Bax) such as Bax, Bad, Bak and Bcl-xS promote
apoptostic processes.
ÚThe gene p53 is a 53-kDa nuclear phospho-protein that binds to DNA to act as a transcription
factor, and controls cell proliferation and DNA repair. Mutations of p53 have been found in > 50%
of human cancers (e.g. colon carcinoma) and are associated with resistance to treatment. The gene
c-myc is a proto-oncogene that encodes a sequence-specific DNA-binding protein that acts as a
transcription factor and induces  in the presence of p53. The c-myc protein is elevated in many
tumours.

Execution phase
Ú
ÚThe central events in  are proteolysis and mitochondrial inactivation. Cellular disruption results
from activation of a family of cysteine proteases called caspases (CASP).
ÚCaspases are proenzymes that have been conserved from nematodes to humans. Ten human caspases
(CASP 1–10) have been described. There are two subfamilies of caspases, the ced-3 subfamily
(produced by ced-3 gene) and the ICE (IL-1β-converting enzyme) subfamily. Caspase 1, which is
related to ICE, is mainly involved in inflammation. The ced-3 caspases are important effectors of
apoptosis. Caspase 8 or FADD-like interleukin converting enzyme (FLICE) is the most important
enzyme of the ced-3 subfamily. The actions of the caspases are varied; some are endonucleases that
cleave DNA, some cleave cytoskeletal proteins and others cause a loss of cell adhesion.
ÚThe integrity of the plasma membrane of the apoptotic cell is maintained initially, although
'budding' of the cell membrane can occur later. There is no leakage of lysosomal enzymes that can
damage nearby cells or elicit immune responses.  The apoptotic cell expresses membrane signals that
induce phagocytosis. Macrophages can recognise neutrophils undergoing  via complexes involving
thrombospondin receptors (CD36) and the αvβ3 integrin.

Mechanisms  of apoptosis
ÚApoptosis can be initiated by two pathways. The death-receptor pathway (extrinsic pathway) is
induced by ligand binding to TNFR superfamily members. Receptors then recruit adaptor proteins
through DD homophilic interactions. Adaptor proteins in turn recruit initiator pro-caspases by DED
interaction, leading to DISC formation. Initiator procaspases are then converted in active caspases
able to cleave substrates such as Bid or effector pro-caspases. The death receptor-induced
triggering of apoptosis is impaired by recruitment of FLIP, an enzymatically inactive initiator
caspase homologue.
ÚThe second pathway (intrinsic pathway) is triggered by mitochondria in response to intracellular
injuries such as DNA damage. Pro-apoptotic members of the Bcl-2 family of proteins induce
mitochondrial release of various molecules such as cytochrome c, which can be counteracted by
anti-apoptotic Bcl-2 family members. Cytochrome c binds to Apaf-1, which upon ATP-dependent
conformational change and oligomerization associates with pro-caspase 9, forming the apoptosome,
which is able to cleave effector pro-caspases. Effector caspase cleavage can be inhibited through
activity of IAP proteins, which are themselves antagonized by the Smac/DIABLO protein released from
mitochondria. Cleavage of Bid ensures the cross-talk between both apoptosis signaling pathways,
since truncated Bid inserts itself in the mitochondrial membranes and induces cytochrome c release.

FIGURE 1. Apoptosis can be initiated by two pathways. The death-receptor pathway (extrinsic
pathway) i...


Apoptosis pathways
ÚIn the past two decades there has been remarkable progress in defining the genes and pathways that
regulate.
ÚSeveral gene families play a pivotal role in regulation of  in endothelial cells as in other cell
types. The caspase family of cysteine proteases includes proteases that initiate  and proteases
that act as executioners, ultimately resulting in the dismantling of the apoptotic cell.
ÚThe Bcl-2 family includes both pro-apoptotic proteins and anti-apoptotic proteins that largely
determine whether a cell lives or dies.
ÚInhibitors of  proteins (IAPs) directly bind and inhibit caspases, and are also important
determinants of cell fate during.
ÚOperationally, one can define 'apoptotic' death as a process mediated by caspases and/or inhibited
by anti-apoptotic Bcl-2 proteins or IAPs. However, it is important to recognize that there are
caspase-independent mechanisms of apoptotic cell death, non-apoptotic functions of caspases, and
functions of Bcl-2 proteins apart from.

Apoptosis-signal for
ÚThe signal that initiates  may result from binding of a cell-surface 'death' receptor or from
damage to the genome. Death receptors that initiate  include the Fas receptor and the TNF receptor
system.
ÚThe Fas receptor is a transmembrane glycoprotein death receptor that is activated by binding of
Fas ligand (Fas-L) to cell membranes. Intracellular molecules known as Fas-associated death domain
(FADD) are produced. Fas receptors are found in epithelial tissues, tumours and haemopoietic
tissues, and may be induced in other tissues that do not express them. The Fas pathway is important
in controlling the immune response. Cytotoxic T lymphocytes expressing Fas ligands activate cells
bearing Fas receptors and induce  apoptosis.

Figure 2 Various initiating triggers effect the activation of a central apoptotic signal. This
central...


Ch6G2



To the previous picture
ÚDeath receptors:  Fas/CD95, DR4/DR5, DR3, and TNFR (Tumor Necrosis Factor Receptor).
ÚAdaptors: FADD (Fas-associated death domain protein) and TRADD (TNFR-associated death domain
protein).
ÚActivation:  Binding of death ligands (FasL/CD95L, TRAIL/APO-2L, APO-3L and TNF) induces
trimerization of their receptors, which then recruit adaptors and activate caspases.
ÚNote: TRADD is involved only in the coupling between caspases and DR3 or TNFR.  This adaptor can
also recruit other proteins to inhibit apoptosis through the NF-kB pathway.
Ú

TNF receptor system
ÚThe TNF receptor system mediates different biochemical pathways. A TNF-related -inducing ligand
(TRAIL) has been discovered. Cancer cells are susceptible to TRAIL-induced apoptosis. Following
binding of the TNF receptor, intracellular molecules called 'death domains' are produced. A TNF
receptor associated death domain (TRADD) has been identified. Tumour necrosis factor may suppress
by binding to the receptor, TNFR2, which activates a protein known as nuclear factor κB (NF-κB),
classed as an inhibitor of  protein (IAP) that prevents the execution phase of apoptosis. It is a
DNA binding protein that regulates many pro-inflammatory genes for the production of cytokines and
other pro-inflammatory molecules.

E:\PREDNASK\obr8.gif



nrm2147-f2



P53-to the previous figure
ÚThe major functional domains of the p53 protein are shown, including the N-terminal
transactivation domains, the central sequence-specific DNA-binding domain and the C-terminal
regulatory domain.
Úp53 is subject to numerous post-transcriptional modifications, including phosphorylation,
acetylation, methylation and modification with ubiquitin-like proteins, that can affect the
function and stability of p53. Phosphatases, de-acetylases and de-ubiquitylating enzymes have been
identified that can reverse most of these modifications.
ÚMost of the point mutations found in naturally occurring cancers occur in the central DNA-binding
domain, and the position of the hotspots for these mutations are indicated by the orange lightning
bolts. The p53-related proteins p63 and p73 show a similar overall structure, although some
isoforms of these p53 relatives also contain a C-terminal sterile  -motif (SAM) domain.

nrm2147-f3



P53-metabolic pathway
ÚSome of the points at which p53 can affect metabolic pathways. This is a new and rapidly moving
area of research, and the influence of p53 on metabolism is likely to be much broader than
illustrated here. In response to nutrient stress, p53 can become activated by AMP kinase (AMPK),
promoting cell survival through an activation of the cyclin-dependent kinase inhibitor p21. Other
functions of p53 include regulating respiration, through the action of SCO2, or in decreasing the
levels of reactive oxygen species (ROS), through the actions of TIGAR (Tp53-inducible glycolysis
and apoptosis regulator) or sestrins.




Fig. 1. Endothelial apoptosis in vascular disease. Diverse stimuli have been reported to induce
endoth...
Endothelial cell apoptosis can lead to disruption of the endothelial barrier with vascular leak,
extravasation of plasma proteins, and exposure of a prothrombotic subendothelial matrix. Apoptotic
endothelial cells are themselves procoagulant and proadhesive in vitro. Endothelial apoptosis thus
has the potential to be an important mechanism of vascular injury and dysfunction
WINN, R. K. & HARLAN, J. M. Journal of Thrombosis and Haemostasis 3 (8), 1815-1824.

Figure 1 The major stages of apoptosis include the initiating trigger (1) that leads to the
activation...


Caspase family
ÚCaspase stands for cysteine-dependent aspartate-specific protease. To date, at least 14 members of
this family have been identified in mammals although not allof them function during apoptosis.
ÚMembers of the caspase family can be divided into three subgroups
Úinitiators in apoptosis (caspase-2, 8, 9 and 10)
ÚExecutioners in apoptosis (caspase-3, 6 and 7)
Úparticipants in cytokine activation (caspase-1, 4, 5, 11, 12, 13 and 14).

Initiator caspases and adaptor proteins
ÚInitiator caspases play a role in initiating the apoptotic pathway. A different combination of
initiator caspases, adaptors and regulatory proteins are required for the control and execution of
different death stimuli.
ÚCaspase-2 is known to mediate stress-induced apoptotic death such as
Úß-amyloid toxicity and trophic factor deprivation.
ÚActivation of caspase-2 involves a large protein complex containing the death domain-containing
protein PIDD and the adaptor protein RAIDD.
ÚCaspase-8 and its adaptor, FADD, are needed for Fas- and TNF-R1-transduced apoptosis althoughthey
are dispensable for other cell death pathways
ÚIn thymocytes and embryonic fibroblasts, caspase-9 and its adaptor Apaf-1 are required for DNA
damage, corticosteroid and staurosporine-induced cell death but not Fas- and TNF-R1-transduced
apoptosis

Initiator caspases and adaptor proteins
ÚCaspase-10 recruitment during TRAIL and Fas mediated  apoptosis also requires FADD.
ÚBoth caspase- 8 and caspase-10 contain death effector domain and they appear to play a major role
in Fas-mediated apoptosis in human T cells.
ÚCaspase-12, which is involved in the maturation of the cytokines, was activated in endoplasmic
reticulum by stress-induced apoptotic signals and, in turn, processed downstream executioner
caspases. In this aspect, caspase-12 may be considered as an initiator caspase.

Executioner caspases
ÚSubsequent to the recruitment and autocatalytic cleavage of caspase-8 and caspase-9, a second
subpopulation of caspases, caspase-3, 6 and 7, are activated.
ÚThese are known as the executioner caspases because they play a key role in the enzymatic cleavage
of a variety of cellular proteins.

Stimuli for apoptosis
DNA (genome) damage
Ionising radiation
Anti-cancer drugs (e.g. alkylating agents)
Activation of death receptors
Binding of 'death receptors' (e.g. Fas receptor, TNF receptor)
Withdrawal of growth factors (e.g. nerve growth factor, IL-3)
Stimulation of apoptotic pathway
Phosphatases, kinase inhibitors
Direct physical cell damage
Heat, ultraviolet light, oxygen free radicals, hydrogen peroxide
DNA, deoxyribonucleic acid; TNF, tumour necrosis factor; IL-3, interleukin-3.

Proapoptotic stimuli
ÚDeath receptors
ÚThe death receptor family of cell surface receptors, including Fas, tumor necrosis factor receptor
(TNFR-1) and TRAIL-R, can initiate  in multiple cell types.
Ligation of the death receptor recruits the adaptor molecule Fas-associated death domain (FADD) and
leads to the aggregation of pro-caspase-8, which auto-activates and then activates downstream
effector caspases such as caspase-3.
ÚThe death receptor ligands, TNFα  and TRAIL, can directly kill endothelial cells in vitro.
TNFα-mediated killing is exaggerated by inhibitors of protein synthesis, due in part to inhibition
of NF-κB-dependent anti-apoptotic proteins.

Proapoptotic stimuli
ÚToll-like receptors
ÚToll-like receptors (TLRs) are pattern recognition receptors that are a significant part of the
innate immune system and share signaling pathways with interleukin-1 (IL-1)/IL-1receptor (IL-1-R).
ÚTLRs and IL-1-R interact with the intracellular adaptor molecules. Signaling induced by ligation
of TLRs and IL-1-R is mostly pro-inflammatory.

Proapoptotic stimuli
ÚOther stimuli
ÚIn addition to death receptor and TLR signaling, a wide variety of stimuli have been reported to
induce apoptosis of endothelial cells in vitro.
ÚThese include antiendothelial cell antibodies (AECA) and antiphospholipid antibodies, infectious
organisms and toxins,  hypoxia  and hyperoxia, angiotensin II, homocysteine, radiation, and
oxidants such as oxidized low-density lipoprotein (oxLDL).

Apoptosis triggered by internal signals: the intrinsic or mitochondrial pathway
Ú
ÚIn a healthy cell, the outer membranes of its mitochondria display the protein Bcl-2 on their
surface. Bcl-2 inhibits apoptosis.
ÚInternal damage to the cell (e.g., from reactive oxygen species) causes
–related proteins, Bad and Bax, to migrate to the surface of the mitochondrion where they bind to
Bcl-2 — blocking its protective effect — and punch holes in the outer mitochondrial membrane,
causing
–cytochrome c to leak out.
ÚThe released cytochrome c binds to the protein Apaf-1 ("apoptotic protease activating factor-1").
Using the energy provided by ATP, these complexes aggregate to form apoptosomes.  The apoptosomes
bind to and activate caspase-9.
ÚCaspase-9 is one of a family of over a dozen caspases. They are all proteases. They get their name
because they cleave proteins — mostly each other — at aspartic acid (Asp) residues).  Caspase-9
cleaves and, in so doing, activates other caspases (caspase-3 and -7).
ÚThe activation of these "executioner" caspases creates an expanding cascade of proteolytic
activity (rather like that in blood clotting and complement activation) which leads to
–digestion of structural proteins in the cytoplasm,
–degradation of chromosomal DNA,
–and phagocytosis of the cell.
Ú

caspase9



Copyright ©2003 American Physiological Society
Mayer, B. et al. News Physiol Sci 18: 89-94 2003;
doi:10.1152/nips.01433.2002
Members of the Bcl-2 superfamily are key regulators of mitochondrial apoptosis
The Bcl-2 superfamily can be subdivided into pro- and antiapoptotic family members

Apoptosis triggered by external signals: the extrinsic or death receptor pathway

ÚFas and the TNF receptor are integral membrane proteins with their receptor domains exposed at the
surface of the cell
Úbinding of the complementary death activator (FasL and TNF respectively) transmits a signal to the
cytoplasm that leads to
Úactivation of caspase 8
Úcaspase 8 (like caspase 9) initiates a cascade of caspase activation leading to
Úphagocytosis of the cell.
Ú

CTL_Fas



Human diseases associated with disordered apoptosis
Increased apoptosis
 Decreased apoptosis
 Central nervous system
Degenerative diseases (Alzheimer's and Parkinson's disease)

Cerebral ischaemia
  Myocardium
Peri-infarct border zones
  Lymphocytes
Lymphocyte depletion in sepsis and HIV infection
  Macrophages
Bacillary dysentery (Shigella dysenteriae)
Decreased apoptosis

  Epithelial tissues
Carcinogenesis
  Blood vessels
Intimal hyperplasia
  Lymphocytes
Autoimmune disorders
  Haemopoietic system
Leukaemia, lymphoma
Kam, P. C. A. & Ferch, N. I. Anaesthesia 55 (11), 1081-1093.

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Wound healing
Úis a natural restorative response to tissue injury.
ÚHealing is the interaction of a complex cascade of cellular events that generates resurfacing,
reconstitution, and restoration of the tensile strength of injured skin.
ÚUnder the most ideal circumstances, healing is a systematic process, traditionally explained in
terms of 3 classic phases: inflammation, proliferation, and maturation.

Wound healing
ÚThe inflammatory phase: a clot forms and cells of inflammation debride injured tissue during.
ÚThe proliferative phase: epithelialization, fibroplasia, and angiogenesis occur; additionally,
granulation tissue forms and the wound begins to contract.
ÚThe maturation phase: Collagen forms tight cross-links to other collagen and with protein
molecules, increasing the tensile strength of the scar.

wound1



Inflammatory Phase
ÚThe body responds quickly to any disruption of the skin’s surface.
ÚWithin seconds of the injury, blood vessels constrict to control bleeding at the site.
ÚPlatelets coalesce within minutes to stop the bleeding and begin clot formation.

Inflammatory Phase
ÚEndothelial cells retract to expose the subendothelial collagen surfaces;
Úplatelets attach to these surfaces.
ÚAdherence to exposed collagen surfaces and to other platelets occurs through adhesive
glycoproteins: fibrinogen, fibronectin, thrombospondin, and von Willebrand factor.

cb09t1977001
Blood clot formation


Thrombus formation
Fibrin
Erythrocytes
Platelets

This scanning electron photomicrograph shows the actual clot formation.  The fibrin "mesh" of
cross-linked fibrin monomers can be seen as a white stringlike substance trapping red blood cells
in a fresh clot.The red cells are not sticking together; they are being held together by fibrin.
Much the same process occurs early in clot development, when platelet aggregates are held together
by fibrinogen, which stabilizes the first hemostatic plug.
Colman RW, Hirsh J, Marder VJ, Salzman EW. Overview of hemostasis. In: Colman RW, Hirsh J, Marder
VJ, Salzman EW, eds. Hemostasis and thrombosis, 3rd ed. Philadelphia: J.B. Lippincott, 1994 pp
6,13,14.

fibrinolysis-clot-formation-PU






Regeneration
Exact replacement of the tissue by the same tissue type cells
Normal reparation
New balance in the tissue
Insufficient healing
Chronic ulcers
Excesive healing
Fibrosis and contractures
Tissue injury
According to Diegelmann and  Evans,2004

Inflammatory Phase
ÚThe aggregation of platelets results in the formation of the primary platelet plug. Aggregation
and attachment to exposed collagen surfaces activates the platelets.
ÚActivation enables platelets to degranulate and release chemotactic and growth factors, such as
platelet-derived growth factor (PDGF), proteases, and vasoactive agents (eg, serotonin, histamine).

Inflammatory Phase
ÚThe result of platelet aggregation and the coagulation cascade is clot formation.
ÚClot formation is limited in duration and to the site of injury.
ÚClot formation dissipates as its stimuli dissipate. Plasminogen is converted to plasmin, a potent
enzyme aiding in cell lysis.
ÚClot formation is limited to the site of injury because uninjured nearby endothelial cells produce
prostacyclin, an inhibitor of platelet aggregation. In the uninjured nearby areas, antithrombin III
binds thrombin, and protein C binds factors of the coagulation cascade, namely, factors V and VII.

Inflammatory phase
ÚBoth pathways proceed to the activation of thrombin, which converts fibrinogen to fibrin.
ÚThe fibrin product is essential to wound healing and is the primary component of the wound matrix
into which inflammatory cells, platelets, and plasma proteins migrate.
ÚRemoval of the fibrin matrix impedes wound healing.

Inflammatory Phase
ÚIn addition to activation of fibrin, thrombin facilitates migration of inflammatory cells to the
site of injury by increasing vascular permeability. By this mechanism, factors and cells necessary
to healing flow from the intravascular space and into the extravascular space.

Inflammatory Phase
ÚPlatelets also release factors that attract other important cells to the injury.
ÚNeutrophils enter the wound to fight infection and to attract macrophages.
ÚMacrophages break down necrotic debris and activate the fibroblast response.
ÚThe inflammatory phase lasts about 24 hours and leads to the proliferation phase of the healing
process.

Proliferation Phase
Ú
ÚOn the surface of the wound, epidermal cells burst into mitotic activity within 24 to 72 hours.
These cells begin their migration across the surface of the wound.
ÚFibroblasts proliferate in the deeper parts of the wound. These fibroblasts begin to synthesize
small amounts of collagen which acts as a scaffold for migration and further fibroblast
proliferation.
Ú

Proliferation Phase
Ú
ÚGranulation tissue, which consists of capillary loops supported in this developing collagen
matrix, also appears in the deeper layers of the wound.
ÚThe proliferation phase lasts from 24 to 72 hours and leads to the maturation phase of wound
healing.

Proliferation Phase
Ú
ÚFour to five days after the injury occurs, fibroblasts begin producing large amounts of collagen
and proteoglycans.
ÚProteoglycans appear to enhance the formation of collagen fibers, but their exact role is not
completely understood.
ÚCollagen fibers are laid down randomly and are cross-linked into large, closely packed bundles.

Proliferation Phase
Ú
ÚWithin two to three weeks, the wound can resist normal stresses, but wound strength continues to
build for several months.
ÚThe proliferation phase lasts from 15 to 20 days and then wound healing enters the maturation
phase.

Picture%2007



Maturation Phase
ÚDuring the maturation phase, fibroblasts leave the wound and collagen is remodelled into a more
organized matrix.
ÚTensile strength increases for up to one year following the injury. While healed wounds never
regain the full strength of uninjured skin, they can regain up to 70 to 80% of its original
strength.

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Picture%2004



Chronic Wounds
ÚFailure or delay of healing components
ÚUnresponsiveness to normal growth regulatory signals
ÚAssociated with repeated trauma, poor prefusion/oxygenation and/or excessive inflammation
ÚSystemic disease
ÚGenetic factors

Factors affecting wound healing
ÚLocal
ÚRegional
ÚSystemic

Local factors affecting wound healing
ÚMechanical injury
ÚInfection edema
ÚIschemia/hypoxia/necrosis
ÚTopical factors
ÚIonizing radiation
ÚForeign bodies

Regional factors affecting wound healing
ÚArterial insufficiency
ÚVenous insufficiency
ÚNeuropathy

Systemic factors affecting wound healing
ÚHypoperfusion
ÚInflammation
ÚNutrition
ÚMetabolic diseases
ÚImmunodefficiency/ immunosupression
ÚConnective tissue disorders
ÚSmoking
Ú

Scar formation
ÚThere are three variable parameters responsible for the pathological evolution of a scar:
Úthe cellular population, the fundamental matrix, and the fibers. The pathological evolution is
produced by:
Údeviations in the continuity of the healing
Údeviations in the reactivity of the organism
Údeviations produced by the traumatic agent
Ú

Figure 5
Keloid scar


keloid_scar
Keloid scarring


Thank you for your attention
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