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TISSUE REPAIR: REGENERATION, HEALING AND FIBROSIS

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TISSUE REPAIR: REGENERATION, HEALING AND FIBROSIS Tissue repair is the response of organisms to overcome the damage caused by toxic insults, inflammation and trauma. – PowerPoint PPT presentation

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Title: TISSUE REPAIR: REGENERATION, HEALING AND FIBROSIS


1
TISSUE REPAIR REGENERATION, HEALING AND FIBROSIS
  • Tissue repair is the response of organisms to
    overcome the damage caused by toxic insults,
    inflammation and trauma.
  • The inflammatory response is not only the first
    to deal with any type of tissue injury, but also
    initiates the process of repair which consists of
    the restoration of tissue architecture and
    function.
  • Some tissues are able to replace the damaged
    cells and tissues in its entirety (regeneration).
  • If the tissue injury is too severe and
    regeneration is not possible, repair occurs by
    laying down fibrous tissue (healing) that results
    in scar formation.
  • Injured tissue can usually function despite the
    presence of scars.

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  • Fibrosis refers to the heavy deposition of
    collagen that occurs in organs such as lungs,
    liver and kidney following chronic inflammatory
    processes or in the myocardium after extensive
    ischemic necrosis (infarction).
  • Fibrosis replacing purulent exudates is called
    organization.
  • Repair involves the proliferation of different
    types of cells and their interaction with the ECM
    (extracellular matrix).

3
CELL PROLIFERATION AND REGENERATION
  • Tissue repair involves the proliferation of
    cells from
  • a) the remnants of the injured tissue
  • b) vascular endothelial cells to form new blood
    vessels
  • c) fibroblasts which provide fibrous tissue for
    the formation of scars.
  • The normal size of the cell population is
    determined by the balance between cell
    proliferation and cell death by apoptosis and the
    appearance of new differentiated cells produced
    by tissue stem cells.

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  • The main steps in the proliferation of cells are
    DNA replication and mitosis and this sequence of
    events is known as the cell cycle.
  • The cell cycle consists of several steps in
    order to check the accuracy of cell division.
  • Non-dividing cells are either in cell cycle
    arrest in G1 or they exit the cycle (G0).
  • Checkpoint controls prevent DNA replication or
    mitosis of damaged cells or eliminate damaged
    cells by apoptosis.

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  • The major action of growth factors is to
    overcome these checkpoint controls by releasing
    suppressors of CDK activity (cyclin dependent
    kinases).

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  • A. Tissue Repair
  • The ability of tissues to repair themselves
    depends on their intrinsic proliferative
    capacity.
  • Based on this principle, the tissues of the body
    can be divided into three groups
  • a) continuously dividing tissues (labile
    tissues) such as hematopoietic cells of the bone
    marrow, stratified squamous epithelium, cuboidal
    epithelium of excretory ducts, and
    gastrointestinal tract.
  • These tissues can easily regenerate after injury
    as long as stem cells are intact.

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  • b) stable tissues cells of these tissues are
    quiescent and have minimal replicate activity.
    However, cells are able to replicate in response
    to injury or loss of tissue mass.
  • Stable tissues constitute the parenchyma of most
    solid organs such as the liver, kidney, and
    pancreas, as well as endothelial cells,
    fibroblasts, and smooth muscle cells.
  • With the exception of the liver, stable tissues
    have a limited capacity to regenerate.

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  • c) Permanent tissues. The cells of these tissues
    are terminally differentiated in post-natal life.
    Cardiac muscle cells and most neurons are in this
    category. Injury to brain and heart muscle
    results in liquefaction, necrosis and scar
    formation.
  • The liver has a great regenerative capacity that
    occurs after surgical removal or injury of
    hepatic tissue.
  • As much as 40 to 60 of the liver may be
    removed in a procedure called living-donor
    transplantation. In this situation, replication
    after partial hepatectomy is initiated by the
    cytokines TNF and IL6 that trigger the transition
    of hepatocytes from stages g0 to g1 in the cell
    cycle.

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  • HGF and EGF provide the progression of
    hepatocytes along the cell cycle.
  • HGF is produced by fibroblasts, endothelial
    cells and liver non-paremchymal cells.
  • HGF also stimulate the proliferation of most
    epithelial cells including those of the skin,
    breast, and lungs.

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  • Extensive regeneration or compensatory
    hyperplasia can take place only if the residual
    tissue of the affected organ is structurally or
    functionally intact.
  • Skeletal muscle is considered permanent tissue.
    However, cells attached to the endomysial sheet
    provide some regenerative capacity.

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  • In continuously dividing tissues, mature cells
    are terminally differentiated and short-lived
    (for example, epidermal cells). The dead cells
    are replaced by cells produced by stem cells
    located at the basal layer of the epithelial
    lining. Cells differentiate progressively as they
    migrate to the upper layers of the mucosa.

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  • Stem cells with the capacity to generate
    multiple cells lineages (pluripotent stem cells)
    can be isolated from embryos (ES cells).
  • Stem cells with similar capacity have also been
    identified in the bone marrow with the capacity
    to generate fat, cartilage, bone, endothelium,
    muscle, as well as all myeloid and lymphoid
    hematopoietic elements.
  • The new field of regenerative medicine deals
    with the regeneration and repopulation of injured
    organs using embryonic or adult stem cells.

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  • B. Growth Factors
  • Cell proliferation is triggered by many chemical
    mediators such as growth factors, hormones and
    cytokines.
  • Growth factors are polypeptide molecules causing
    an expansion of cell populations which include an
    increase in cell size, mitotic activity and
    protection from apoptotic death (survival).
  • In addition to stimulating cellular
    proliferation, they promote cellular migration,
    differentiation, contractibility, as well as
    enhancing the synthesis of special proteins such
    as collagen by fibroblasts.

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  • C. Repair by Connective Tissue
  • If extensive tissue surgery is performed or if a
    chronic inflammatory process causes damage to
    parenchymal cells, epithelia and stromal network,
    repair cannot take place by regeneration alone.
    The same thing happens when non-dividing cells
    are injured.
  • In this situation, repair occurs by replacing
    the necrotic tissue with connective tissue or by
    the combination of regeneration of some cells and
    scar formation.
  • The extracellular matrix (ECM) is an essential
    participant of the repair process.

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  • D. Structure and Function of the ECM
  • Tissue repair depends not only on growth factor
    activity, but also on interactions between cells
    and ECM components.
  • The ECM is a dynamic, constantly remodeling
    macromolecular complex creating a network that
    surrounds every cell.

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  • The ECM can be divided in two basic forms
    interstitial matrix, and basement membrane.
  • The interstitial matrix is present in connective
    tissue between epithelium and supportive vascular
    and smooth muscle structures.
  • It is synthesized by mesenchymal cells
    (fibroblasts) and tends to forms a
    three-dimensional amorphous gel.
  • The basement membrane lies beneath the
    epithelium and is synthesized by overlying
    epithelium and underlying mesenchymal cells. It
    is a highly organized ECM around epithelial,
    endothelial, and smooth muscle cells.

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  • The ECM has three basic components
  • a) fibrous structural proteins such as collagens
    and elastins
  • b) water hydrated gels, hyaluronan and
    proteoglycans
  • c) adhesive glycoproteins and adhesion receptors

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  • a) Collagens and elastins
  • There are basically two types of collagen the
    fibrillar types (I, II, and V) and the
    non-fibrillar types (IV and IX).
  • The fibrillar collagens form a major portion of
    the connective tissue of healing wounds and scars
    as well as the interstitial matrix. The synthesis
    of these collagens are Vitamin C dependent.
  • The nonfibrillar collagen (Type IV) is a
    component of the basement membrane.

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  • Elastin consists of a core of elastin surrounded
    by a mesh-like network of fibrillin glycoprotein
    and is the main component of elastic tissue.
  • It has the ability to recoil and return to a
    baseline structure after physical stress.
  • Elastin is also part of the interstitial matrix.

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  • b) Proteoglycans and Hyaluronan
  • Proteoglycans are highly hydrated, compressible
    proteins providing resilience and lubrication
    (cartilage and joints).
  • It consists of long polysaccharides called
    glycosaminoglycans (heparan sulfates) linked to a
    protein backbone.
  • Proteoglycans may be components of the cell
    membrane and have roles in cell proliferation,
    migration, and adhesion.
  • Hyaluronan is composed of many disaccharide
    repeats without a protein core.
  • It binds water, forming a viscous, gelatin-like
    matrix.

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  • c) Adhesive glycoproteins and adhesion receptors
  • These compounds are involved in cell to cell
    adhesion, the linkage between cells and ECM and
    binding between ECM components.
  • The adhesive glycoproteins are fibronectin,
    which is a major component of the interstitial
    ECM and laminin which is part of the basement
    membrane.
  • These are synthesized by fibroblasts, monocytes
    and epithelium.
  • Fibronectin binds to many components of the ECM
    (collagen, proteoglycans) and can also attach to
    cell integrins.

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  • There are two types of fibronectin tissue and
    plasma.
  • Tissue fibronectin forms fibrillary aggregates
    at wound healing sites, while plasma fibronectin
    binds to fibrin to form a provisional clot of a
    wound that serves as the base for ECM deposition
    and reepithelization.
  • Laminin is the most abundant glycoprotein of the
    basement membrane.
  • It mediates attachment to the BM and modulates
    cell proliferation, differentiation, and motility.

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  • Adhesion receptors, also known as CAMs (cell
    adhesion molecules), are divided in four groups,
    namely immunoglobulins, cadherins, selectins,
    and integrins.
  • Integrins are present in most animal cells
    except red cells.
  • These are present in the surface of leukocytes
    that mediate cell adhesion and transmigration and
    are the main cellular receptors for the ECM
    components.
  • By linking to intracellular domains (actin)
    integrins initiate signaling cascades affecting
    cell locomotion, proliferation, and
    differentiation.

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  • E. Summary of the roles of the ECM
  • In addition to filling spaces around cells, the
    ECM does the following
  • Provide mechanical support for cell anchorage,
    migration and maintenance of cell polarity.
  • b) Control of cell growth by signaling through
    link with intracellular integrins.
  • c) Affect the degree of differentiation of the
    cells in a given tissue via
    cell surface integrins.
  • d) Provide scaffolding for the basement
    membrane and interstitial cellular matrix. The
    integrity of the ECM is critical for the
    organized regeneration of parenchymal cells.

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  • e) Establishment of tissue microenvironments. The
    basement membrane acts as a boundary between
    epithelium and underlying connective tissue.
  • f) Storage and presentation of regulatory
    molecules like growth factors FGF and HGF,
    synthesize by epithelial and stromal cells,
    allowing for rapid deployment of growth factors
    after local injury or during regeneration.

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Repair by Connective Tissue
  • It involves the replacement of dead cells and
    tissues with connective tissue leading to scar
    formation. The sequence of this process is as
    follows
  • 1) Repair begins within 24 hours of the time
    of injury by the emigration of fibroblasts and
    the induction of fibroblast and endothelial cell
    proliferation.
  • 2) After 3 to 5 days, it begins the formation
    of granulation tissue which is pink and soft,
    with a granular appearance such as seen
    underneath the scab of an injured skin.
    Histologically, it is composed of proliferating
    fibroblasts, newly formed thin capillaries and
    loose ECM.

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Granulation Tissue
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  • Angiogenesis.
  • Blood vessels are formed by vasculogenesis
    originated by angioblasts (endothelial precursor
    cells (EPCs)) present in the bone marrow or by
    neovascularization, where preexisting blood
    vessels send out capillary sprouts to produce new
    vessels.
  • Angiogenesis is involved in the development of
    collateral circulation at sites of ischemia and
    allowing tumors to increase in size. EPCs may
    migrate from the bone marrow to areas of injury
    but the homing mechanism is not known.

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Vasculogenesis
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  • Capillaries present in granulation tissue are
    leaky due to defective endothelial junctions and
    because VEGF increases vascular permeability.
    This leakiness explains why granulation tissue is
    edematous, and the persistent presence of edema
    in healing wounds.
  • ECM proteins participate in vessel sprouting
    through interaction with integrin receptors of
    endothelial cells. They also interfere with ECM
    cell interactions which facilitate the migration
    of endothelial cells.
  • The most important growth factors involved in
    angiogenesis are VEGF and FGF2.

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  • 3) Migration of fibroblasts and ECM deposition
    (scar formation).
  • Scar formation takes place on the network of the
    newly formed granulation tissue and loose ECM.
    The scar develops in two steps
  • Migration and proliferation of fibroblasts at the
    injury site, and
  • b) deposition of ECM by fibroblasts.

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  • The migration and proliferation of fibroblasts
    is triggered by several growth factors such as
    PDGF, FGF, and TGF2. These are synthesized by
    activated endothelial and inflammatory cells,
    especially macrophages which also clear
    extracellular debris and elaborate mediators that
    induce fibroblast proliferation and ECM
    components.
  • The fibroblast migration starts early in
    wound healing, and continues for several weeks,
    depending on the size of the wound.
  • As the healing progresses, there is a decrease
    of the number of proliferating fibroblasts and
    newly formed blood cells but there is an increase
    in the deposition of ECM, particularly collagen.

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  • Eventually, the granulation tissue becomes a
    scar composed of inactive spindle-shaped
    fibroblasts, dense collagen, fragments of elastic
    tissue, and other ECM components.
  • There is also a progressive vascular regression
    resulting in a pale avascular scar.

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Early Scar Formation
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Fully Developed Scar
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Normal Myocardium
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Acute Myocardial Infarction
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Healing Myocardial Infarct
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Healed Myocardial Infarct
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Healed Myocardial Infarct
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  • TGFB is a potent fibrogenic agent. It simulates
    production of collagen, fibronectin, and
    proteoglycans, and it inhibits collagen
    degradation.
  • It also inhibits lymphocyte proliferation and
    has a strong anti-inflammatory effect.
  • PDGF is produced by endothelial cells, activated
    macrophages, smooth muscle cells and many tumor
    cells. It is stored in platelets and released on
    platelet activation. PDGF causes migration and
    proliferation of fibroblasts, smooth muscle cells
    and macrophages.
  • Cytokines like 1L, and TNF may also function as
    growth factors by inducing fibroblastic
    proliferation and fibrogenic effects. They are
    also chemotactic for fibroblasts and stimulate
    the synthesis of collagen and collagenase.

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  • 4) ECM tissue remodeling.
  • After scar deposition, the ECM continues to be
    modified and remodeled. The outcome of the repair
    process depends on the balance between ECM
    synthesis and degradation.
  • The degradation of collagen and ECM is done by
    matrix metalloproteinases (MMPs) which are zinc
    dependent. ECM can also be degraded by neutrophil
    elastase, cathepsin, plasmin, and other serine
    proteases.

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  • MMPs are produced by fibroblasts, macrophages,
    synovial cells and some epithelial cells. Their
    synthesis and secretion are regulated by growth
    factors, cytokines and other agents. Their
    synthesis is inhibited by steroids, TGF, and TIMs
    (tissue inhibitors metalloproteinases). The
    activity of MMPs is tightly controlled.
  • CUTANEOUS WOUND HEALING
  • This process involves epithelial regeneration
    and scar formation.
  • Reepithelialization of the wound surface happens
    by cell migration from the edges of the wound,
    triggered by the interaction between growth
    factors and the ECM.
  • Cutaneous wound healing ends with scar formation
    following the steps already described. It may
    occur by first or second intention.

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  • Healing by first intention or primary union
    takes place on wounds with focal damage of the
    basement membrane and the death of few epithelial
    and connective tissue cells.
  • In this instance, epithelial regeneration
    predominates over fibrosis. A small scar is
    formed with minimal wound contraction. The
    incisional space is filled with fibrin clotted
    blood, rapidly invaded by granulation tissue and
    covered by new epithelium.
  • The whole process is usually completed in two
    weeks, with the formation of a thin scar which is
    covered by normal epidermis in approximately one
    month.

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Normal Skin
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  • Healing by second intention takes place when
    cell and tissue loss is extensive, such as large
    wounds, abscesses, ulcerations, or ischemic
    lesions of solid organs. This healing process is
    also called secondary union.
  • In this type of healing, a large clot or scab
    rich in fibrin and plasma fibronectin forms at
    the surface of the wound. The inflammatory
    response is severe, because large tissue defects
    have a great volume of necrotic debris that must
    be removed.
  • A large amount of granulation tissue is formed
    in order to fill the gap and to allow regrowth of
    epithelium and formation of a usually large scar.
  • At the end of the process, there is contraction
    of the wound (5 to 10 of the original size,
    brought about by myofibroblasts).

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  • Eventually there is a recovery of the tensile
    strength of the wound is brought about by
    collagen synthesis that exceeds degradation.
  • After three months, wound strength reaches 70 to
    80 of the normal unwounded site.
  • Pathologic aspects of repair
  • Several conditions may alter the process of
    repair, causing either inadequate scar formation,
    or an exuberant deposition of collagen and ECM,
    leading to the formation of a prominent raised
    scar.

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  • Production of an inadequate scar or delay in
    scar formation may be due to the following
  • 1) Infection is the most common cause of delay in
    healing, by prolonging the inflammatory response
    and by increasing local tissue injury.
  • 2) Poor nutrition and specially Vitamin C
    deficiency inhibits collagen synthesis and
    retards healing.
  • 3) Glucocorticoids have a known anti-inflammatory
    effect and their administration results in poor
    wound strength due to diminished fibrosis.
  • 4) Mechanical variables such as local pressure or
    torsion may cause wounds to pull apart or dehisce.

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  • 5) Poor perfusion secondary to arteriosclerosis,
    diabetes, or obstructive venous drainage also
    impairs healing.
  • 6) Foreign bodies like glass fragments, steel
    fragments, or bone may disturb healing.
  • Aberrations of cell growth may be due to a
    genetic predisposition (Keloid formation). This
    condition is more common in African American
    patients.

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Review of Repair Responses
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