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Integumentary System & Wound Care
October 24, 2005Michael S. Brogan, PT, PT, PhD, CWS
WOUND HEALING MODELS
• Superficial Wound Healing
• Primary Intention Wound Healing
• Delayed Primary Intention Wound Healing
• Partial-Thickness Wound Healing
• Secondary Intention Wound Healing
Superficial Wound Healing
• Superficial Skin Lesions– Pressure (shearing & friction)
– First degree burns
– Contusions
• Stimulates an inflammatory repair process
• Soft tissues heal themselves over time
• Interventions can hasten process (athletes) prevention of further complication (MO)
Primary Intention Wound Healing
• Drawing wound edges together (sutures)– Three considerations
• No major loss of subcutaneous tissue
• edges are smooth and clean cut
• Wound is not contaminated with microorganisms or foreign bodies
– Result• Minimal scarring, closure 3-7 days
Delayed Primary Intention Wound Healing
• Wounds contaminated with microorganisms or foreign bodies
• Wounds with large tissue loss
• Wounds where intolerable tissue tension would occur
• Wound is at risk of infection (time)
– * Wound is left open
– * Sutures are placed in subcutaneous & fascial layers
– * Wound is usually closed (sutures) in 5 -7 days after infection risk is significantly decreased or tissue loss is replaced
Partial Thickness Wound Healing
• Partial-Thickness loss of the dermis– Abrasions
– Skin tears
– Stage II pressure ulcers
– Second degree burns
• Following injury body immediately begins repair process
• Inflammation Epithelialization
Secondary Intention Wound Healing (by contraction)
• Chosen method when wound extends through full thickness of the skin– When large amounts of tissue are lost– Irregular wound edges cannot be approximated– Non-viable wound margins– High microorganism count– Debris or necrosis
Three Overlapping Phases of Repair With Secondary Intention
• Inflammation
• Repair (Proliferation)– Epithelialization
• Remodeling
Inflammation
Proliferation
Remodeling
Secondary Intention (by contraction)
• Occurs with contraction forces by myofibroblast draw the wound edges together
• Little epithelialization
• Scar tissue formation
• Scar does not replicate the tissue replaced
– Ex (muscle, tendons, nerves)
• Surface tissue is less elastic with decreased tensile strength
• Following Wound Closure, remodeling continues 6 months to 2 years
Skin Grafts
• If wound is in an area where contraction will disfigure or create non-functional deformation, secondary intention used to allow for the development of a good healthy wound bed.
• With healthy wound bed a Split-Thickness Graft can be placed on the granulating wound bed.
Secondary Intention
• Mechanism for Healing of Chronic Wounds
Acute Wound Healing Biology
• Cascade of Overlapping Events (organized & predictable)– Inflammation– Repair (proliferation - epithelialization)– Remodeling
• Biologic Repair Process Same for all Wounds, Open & Closed, Regardless of Etiology
• Sequence hastened with primary intention or with superficial/partial-thickness wounds
• Slower process with Full-Thickness Wounds with extension to subcutaneous tissue
Acute Wound Healing
• Inflammatory Phase 1-10 days – Essential for healing
• Repair Phase 3-20 days
• Remodeling Phase 9 days and on
RemodelingInflammation
Repair
Inflammatory Phase• Vascular & Cellular Response• Hemostatic Mechanisms
– Curtail blood flow– Reduces oxygen delivery to the wound– Produces hypoxia
• Key signal to control wound healing• Too much O2 will impede wound healing• Hypoxia recruits endothelial cells & serves as facilitator for
angiogenesis for repair phase• Local hypoxia causes shift to anaerobic glycolysis, which
increases lactate production which also activates angiogenesis and collagen synthesis
• Wound space thus becomes hyperlactic & acidotic
Hemostatic Mechanisms
• Platelets• First to arrive at injury site
• Release Serotonin
• ADP
• PDGF
• Changes Thromboplastin -Thrombin -Fibrinogen - Fibrin
• Clot
• Protection of Injured Area, delays bacterial invasion
Hemostatic Mechanisms Continued
• Vessel Wall– Endothelial Cell
• Damage activates Hageman Factor XII
• Neutrophils Marginate– Prevent pathogenic invasion
Vascular Reactions
• Vasoconstriction
• Vasodilation
• Edema/Drainage
Vasoconstriction
• First response to trauma
• Vasoconstriction/ norepinephrine
• Vasoconstriction/serotonin
• Adhesion of opposing endothelial surfaces
Vasodilation
• Secondary response to trauma
• Histamine released from mast cells
• increases capillary permeability
• Capillary permeability allows clotting proteins, WBC’s and other fluids from blood into injured area
Edema/Drainage
• Serous………….……………Clear, Watery
• Sanguineous……………Tinge of Red, Thin
• Purulent..…………………Creamy, Thick– Yellow/Brown/Green/Blue
SEROUS
Sanguineous
Purulent
Sussman, C., Bates Jensen, B. (2001). Wound Care 2nd addition. Aspen, Gaithersberg, Md
Plasma Proteins
• Albumin– Small plasma protein
• Gamma Globulins– Medium size protein
• Fibrinogen– Large size plasma protein
– Converted to fibrin by thrombin
– Fibrin plugs seal off lymphatics to prevent spreading infection• Venous Insufficiency
Necrotic Tissue• Scab
– Dehydrated crust formed by coagulated blood, pus, serum
• Eschar
– Thick, dry, black, leathery necrotic tissue
• Mechanical Impediment
– Impedes epithelial cell migration
– Delays granulation tissue formation
• Prolongs Inflammation
– Wounded tissues are struggling to achieve homeostasis
– WBC’s are trying to digest, dissolve and remove necrotic tissues
– Provides a source for pathogens
Cardinal Signs of Inflammation
• Erythema (change in color, red, blue, purple)• Heat (temperature)• Edema (turgor, swelling)• Pain (sensation)• Loss of function• “flare”
– Sudden response - color & temperature• “flaring up a fire”
From: Myers, B.A. (2004).Wound ManagementPrinciples and Practice. Prentice Hall, Saddle River, NJ)
Talking Points– Perfusion & Nutrition Biologic Basis for Signs & Symptoms of
Inflammation• Vasodilation- increased perfusion & capillary pressure
• Allows plasma proteins to migrate into surrounding tissues
• Fibrin plugs seal off lymphatic flow
• Increased blood flow brings nutrients, to meet high metabolic needs
• High metabolic activities & increased blood flow increases tissue temperature
• Rise in Temperature provides an environment favorable for cell mitosis and enhanced cellular activities
Talking Points
• Pain
– Bleeding into tissues releases histamine and protaglandins, which stimulate dilation of injured blood vessels in adjacent tissues & pain afferents of the SNS (Reflex Hyperemia)
• Infection
– Oxygen essential to prevent infection & to meet metabolic demands of the tissue as well as hydroxylation of proline in the biosynthesis of collagen for remodeling wound
How to Facilitate Inflammatory Phase
• Keep Wound Moist
• Remove Necrotic Tissue
• Prevent re-injury to wound
(From: Myers, B.A. (2004).Wound Practice. Prentice Hall, Saddle River, NJ)
Cellular Reactions in Inflammatory Phase
• Granulocytes
– Term for WBC containing many secretory granules
– Polymorphonuclear leukocyte (PMNL) common term for neutrophil granulocyte (nucleus divided into lobes)
– 65% of leukocytes in circulating blood are granulocytes
• 3 types– Neutrophils (PMNL)
– Eosinophils
– Basophils
Neutrophils
• Present in early phase of inflammation (within 24 hrs.for 6 hrs to several days)
• Length of stay depends on bacterial count
• Most phagocytic of WBC (along with macrophages)
• Proliferate in hypoxic acidotic environment
• Produce superoxide to fight bacteria
• Secrete proteases and collagenases (enzymes)
• Destroys pathogens and hydrolyzes necrotic tissue
• Primary cell responsible for cleansing the wound of microorganisms
• Lack of neutrophils will inhibit healing in infected wounds
Neutrophils
• If bacterial count exceeds 100, 000 infection becomes apparent
• Wound pours forth pus (accumulation of dead neutrophils that have phagocytized debris in the wound)
• Short lifetime because it cannot regenerate spent lysosomal and other enzymes used for destruction of foreign substances
• Produces numerous toxic byproducts (OH, superoxide), if excessive neutrophil activity due to high bacterial counts wound tissue & healthy tissue can be negatively affected.
Eosinophils
• Term based on the staining (Red) of cytoplasmic granules
• Modulate allergic inflammatory responses
Basophils
• Release histamine– Increases inflammation– Increases vasodilation– Increases capillary permeabilty
Mast Cells• Specialized secretory cells, granules contain several biologically
active substances including neutrophil chemotactic factor which attracts leukocytic cells that in turn act as chemical signals for the recruitment of macrophages.
• Histamine released from mast cell initially following injury for vasodilation and increased permeability - mild edema
• In low amounts histamine has been shown to stimulate collagen formation and healing
• Mast cells also release heparin which stimulates the migration of endothelial cells.
• Heparin also accelerates the activity of the leukocytes in the phagocytosis of the hematoma following initial wounding of the blood vessels
Macrophages• Differentiate from monocytes once they leave the bloodstream
• Perform several vital functions during inflammatory phase
• Large phagocytic cell, can ingest large microorganisms & debris controlling infection by excreting ascorbic acid, hydrogen peroxide and lactic with a build up of these substances more macrophages will be recruited resulting in an intense prolonged inflammatory phase
• Important regulatory cell and is long lived (months to years)
• Macrophages attract fibroblasts, endothelial cells, and vascular smooth muscle cells
• Both Neutrophils & Macrophages function in a low-oxygen high acidotic environment
• Macrophages are essential for the transition between the inflammatory and repair phases
Macrophages
• Secrete Angiogenesis Growth Factor (AGF) which stimulates the budding of endothelial from damaged blood vessels
• Reestablishment of the blood supply is essential to deliver nutrients, oxygen and toilet the newly forming tissue
• Secretions of Macrophages and dead platelets combine to produce fibroblast- stimulating factor which provide a chemotactic message to the fibroblasts during the late stages of the inflammatory phase
• Macrophages transcend all phases of healing
Lymphocytes
• Immunologically important
• Responsible for primary immune response to pathogens
B Lymphocytes
• B cells release antibodies into bloodstream (referred to as the humerol response)
• Antibodies are immunoglobin (protein) which bind to an antigen (pathogenic)
T Lymphocytes
• T cells responsible for cell- mediated responses
• “helper cells” assist in B cloning
• “suppressor cells” cause B cells to stop cloning
Defense Against Microorganisms
• Epithelium
• Neutrophils & Macrophages
• T & B Cells
Chemical Mediators Inflammatory Phase
• Histamine– Released primarily from mast cells, also from basophils
& platelets– Vasodilator which increases permeability of capillaries
& arterioles
• Serotonin– Powerful vasoconstrictor , from platelets & mast cells– Early phase of inflammation stimulates smooth muscle
contraction
Chemical Mediators Inflammatory Phase (cont.)
• Kinins– Polypeptides (two or more a.a.)– Relax smooth muscle cells of vasculature– Produces vasodilation, increased permeability– Ex. Bradykinin one type of plasma kinins
Chemical Mediators Inflammatory Phase (cont.)
• Prostaglandins (PG’s)– PG’s, fatty acid derivatives– Local mediators, many tissues & fluids– Extremely active biological substances– Increase vascular permeability– Chemotactic substances (attracts other cells)– * steroids and aspirins reduce prostaglandin
production
Chronic Inflammation
• Inefficient cellular activity
• Misuse of cytotoxic agents
• Frequent irritation
• Presence of pathogens
• Infection
• Granuloma
• Repeated trauma (spitting silk)
Repair/ Proliferative Phase
• Fibroplasia
• Granulation/Angiogenesis
• Contraction
• Reepithelialization
From: Myers, B.A. (2004).Wound ManagementPrinciples and Practice. Prentice Hall, Saddle River, NJ)
Fibroplasia• Fibroblasts
– Respond to chemotactic substances from the macrophages
– build the collagen matrix (polypeptide chains)
– Procollagen - tropocollagen - collagen fibril - array of filaments
– Cross-linkage welding together of the collagen matrix
• Produces durability and tensile strength
• the better the organization & cross-linkage,
the better the tensile strength of the scar
– Elastin- provides elastic properties
Hunt & Dunphy (1979). Appleton-Century Crofts, NY
Fiboplasia
• Fibroblasts (cont.)– Glycoproteins
• Laminin & Fibronectin provide structure & metabolic support to other tissues
• Myofibroblasts (contain actin & myosin)– Differentiate from fibroblasts
– Contract & extend
– Draw the edges of the wound together
– Influence rate & amount of wound contraction
Collagen Matrix
• Collagen, Fibronectin, Laminin, Elastin, Acid & new vascular network produced by endothelial cells
• Looks like red granules piled on top of each other
• Granulation Tissue
• Pink granulation buds may be the first sign of repair in a wound
Granulation/Angiogenesis
• Endothelial cells– Respond to AGF secretions of macrophages &
from hypoxic environment– Development of new blood vessels or
vascularization of the tissue that will grow on the collagen matrix (gives bright red appearance of granulation tissue)
Granulation/Angiogenesis• Endothelial cells form new capillaries• Capillaries perfuse the collagen matrix• Red granular appearance• GT matrix of collagen, acid, laminin, fibronectin,
elastin,• Provides matrix upon
which epithelial cell
migration can occur
Sussman, C., Bates Jensen, B. (2001). Wound Care 2nd addition. Aspen, Gaithersberg, Md
Contraction
• Occurs in full-thickness wounds
• The entire thickness of the periwound tissue moves centripetally by action of the myofibroblasts
From: Myers, B.A. (2004).Wound ManagementPrinciples and Practice. Prentice Hall, Saddle River, NJ)
Re-Epithelialization• Superficial wounds heal by reepithelialization • Epithelial cells respond to a break in the skin &
from the dermal appendages• Epithelial cells line skin appendages (hair
follicles, sebaceous glands, sweat glands)• The resurfacing process
immediately following injury
Epithelial Cells
• Specialized function - debridement of necrotic tissue by release of lytic enzymes- lyse the attachment of necrotic tissue to the wound bed
• Migration of epithelial cells O2 dependent– Low levels of O2 & epithelial cells cannot
migrate to debride the wound
Reepithelialization (cont.)
• Epithelial cell migration occurs towards the center of wound from edges
• Contact inhibition stops migration (curled/rolled edges)
• Reepithelialization 4 step process– Mobilization - migration - proliferation- differentiation (mature
into Type I collagen) .… new skin 15 % strength of original
• 70% to 80% of original strength
Remodeling Phase
• Scar maturation occurs
• Fibroblasts disappear
• Collagen reorganizes and scar exhibits greater strength
• Compression garments - burn patients
• Appropriate to massage soft tissue in early maturation phase
Sussman, C., Bates Jensen, B. (2001). Wound Care 2nd addition. Aspen, Gaithersberg, Md
Collagen Lysis
• Collagenase - enzyme responsible to regulate fibroplasia, creates balance between synthesis & lysis of collagen
• Cleaving or breaking the cross-linkage of the tropocollagen molecules
• Collagenase as a debriding agent (Santyl)
• As wound matures collagen lysis increases
Balance
• Collagen synthesis oxygen dependent - collagen lysis is not
• Too much oxygen can cause hypertrophy of the granulation tissues (hypergranulation)
• Better organization of the collagen produces a better functional outcome, more elastic, smoother, and stronger
Remodeling Errors• Hypertrophic Scar
• Keloid Formation– Genetic inhibition of lysis, unbalanced
synthesis and lysis of collagen
Remodeling Errors (cont.)• Control-
– pressure garments to reduce perfusion & oxygen inflow, synthesis is suppressed & lysis continues
– Silver nitrate “knock down the granulation tissue, allowing epithelial migration
– Electrical stimulation; + polarity
Talking Point
• Wound is considered Closed when the epithelial integrity has been restored
• Wound is considered Healed after it has been resurfaced, and tissue strength approaches normal
Chronic Wound Healing
• Deviation from normal sequence of repair in terms of time, appearance, and response to appropriate treatment
• 2 - 4 weeks
• Halo of redness
Abnormal Wound Healing
• Healing is slower than expected• Abundance or reduction of the typical
characteristics of each phase of wound healing
• Underlying causes should be investigated– Local & systemic factors– Iatrogenic factors– Other factors (drugs, radiation, age, etc)
Absence of Inflammation
• Inflammation is a necessary & desirable element of wound healing
• Reduced or absent inflammation may be seen in patients taking high doses of steroids, malnutrition, elderly, immune disorders (HIV, AIDS)
Chronic Inflammation
• May continue for months or years
• Characterized by an increase in macrophages & fibroblast proliferation
• New tissue cannot be built in an inflammatory environment
– Causes• Presence of foreign body in the wound
bed
• Repetitive mechanical trauma
• Use of cytotoxic agents
Hypogranulation
• Absence of a successful proliferative phase
• Insufficient granulation tissue to fill wound defect (pot-hole type wound)
• Epithelial cells cannot bridge the gap
• Rolled edges
Hypergranulation
• Granulation continues after the wound defect has been filled
• Appears as a mound of granulation tissue extending above the surface of the epithelium (proud flesh)
• Epithelialization cannot proceed
Hypertrophic Scarring• Over production of immature collagen• More likely to occur in wounds that cross lines of tension in
the skin or in wounds with a prolonged inflammatory phase (large or infected wounds)
• Burns because of their lengthy proliferative phase• Often associated with contractures
(random over production of collagen• Darker skin individuals
greater propensity** contained within the confines
of the wound
Keloids• Result from excessive immature collagen
synthesis• More common in individuals with more highly
pigmented skin & in areas of increased tissue tension
• Extend outside the confines of the wound
• Commonly associated with tissue trauma
Contracture
• Pathological shortening of scar tissue resulting in deformity
• Likely to occur in wounds crossing a joint (especially burns)
• Position of comfort are usually maintained resulting in adhesions and adaptive shortening of muscles, tendons, and joint capsules
• Decreases movement & limits function
Dehiscence• Separation of wound margins due to
insufficient collagen production or tensile strength
• Common misconception is that infection causes dehiscence
• Longtime steroid use, diabetes mellitus, & malnutrition increase
Kloth, L.C., McCulloch, J.M. (2002)
Types of Wounds
• Arterial
• Venous
• Pressure (STG I, II, III, IV)
• Neuropathic (Diabetic)
• Traumatic (injury/surgery)
• Rheumatoid
Wound Healing Model - Review
• Inflammatory Phase– Vasoconstriction– Hemostasis– Vasodilation– Phagocytosis
Key Cells of the Inflammatory Phase• Platelet
– Forms platelet plug to control bleeding– Secretes growth factors & chemotactic agents
• Polymorphonuclear Leukocyte – Neutrophil– First cells to the site of injury– Scavenger– Kills bacteria– Cleans wound– Secretes inflammatory mediators
• Mast Cell– Secretes several biologically active substances– Secretes inflammatory mediators
• Macrophages– Directs repair process– Assists with killing bacteria and cleaning wound– Secretes growth factors
Proliferative Phase
• Angiogenesis/Granulation
• Collagen Synthesis/Fibroplasia
• Contraction
• Reepithelialization
Proliferative Phase
• Key Cells– Angioblast
• Forms new blood vessels
– Fibroblast• Builds granulation tissue
– Myofibroblast• Causes Wound Contraction
– Keratinocyte• Reepithelializes wound surface
Remodeling Phase
• Collagen Synthesis - Lysis Balance
• Collagen Fiber Re-organization
Wound Healing Model
• Wound– Inflammatory Phase– Repair Phase– Remodeling Phase
• Closed Wound
• Healed Wound
Fetal Wound HealingResearch
• Lack of Scar tissue in fetuses that have fetal surgery in utero
• Amniotic fluid rich in Hyaluronic acid & fibronectin with other growth factors
• Low oxygen levels, differences in immune systems, histology, fibroblasts, absence of myofibroblasts
References• Arndt, A.A., Wintroub, B.U., Robinson, J.K., LeBoit, P.E. (1997).
Primary Care Dermatology. W.B. Saunders Company: Philadelphia, Plate 5, 12, 57-81.
• Du Vivier, A. (1995). Dermatology in Practice. Mosby-Wolfe: New York, 1-11, 25, 53, 94, 97, 100.
• Fitzpatrick, T.B., Johnson, R.A., Wolff, K., Polano, M.K., Suurmond D. (1997). Color Atlas and Synopsis of Clinical Dermatology: Common and Serious Diseases. McGraw-Hill: Health Professions Division: New York.
• Kloth, l.C., McCulloch, J.M. (2002). Wound Healing Alternatives in Management (3rd ed.). F.A. Davis Company, Philadelphia, PA. Plate 17.
• Myers, B.A. (2004). Wound Management: Principles and Practice. Prentice Hall: Upper Saddle River, New Jersey, 37-45, 369-391.
• Sussman, C., Bates-Jensen (1998). Wound Care: A collaborative Practice Manual for Physical Therapists and Nurses. Aspen: Gaithersburg, Maryland.
• White, G.M., Cox, N.H. (2002). Diseases of the Skin: A Color Atlas and Text. Mosby: New York, 1, 3, 5.