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The Surgical Wound Cormac Joyce Final Med 2009

Surgery It is the branch of medicine concerned with diseases and conditions which require or are amenable to operative procedures It is derived from Greek “cheirourgia” “ cheir” = the hand “ ergon” = work

Surgery It is often said that it is “controlled trauma” Carried out in a sterile environment Under aseptic conditions

Surgery Many protocols are put in place to prevent infections in surgical wounds Hand washing Gowns and gloves Painting and draping Drains Antibiotics Laminar flow theatres Sterile instruments Sterile dressings

Surgery But wound infections can occur despite these measures causing: Death Morbidity Longer hospital stays Cosmetically displeasing wounds

Surgery Surgical wound infections are common Comprising 12% of nosocomial infections The rate of infection depends on the type of surgery undertaken

Operation Types The risk of a wound infection depends on the operation For that reason, operations are classified into distinct types Clean Clean-Contaminated Contaminated Dirty

Class I :Clean wounds Elective operations (non emergency) Non traumatic injury Good surgical technique Respiratory, gastrointestinal, biliary and genitourinary tracts not breached Risk of infection < 2% Eg: mastectomy, hernia repair

Class II: Clean - Contaminated Urgent or emergency case that is otherwise clean GI, GU or respiratory tracts entered electively, no spillage or unusual contamination Minor break in sterile technique occurred Endogenous flora involved Risk of infection: <10 % Eg: appendicectomy, bowel resection

Class III: Contaminated Non-purulent inflammation Gross spillage from GIT, entry into GU or biliary tract in the presence of infected bile/urine. Major break in technique Penetrating trauma < 4hrs old Chronic open wounds Risk of infection: 20% Eg: GSW, rectal surgery

Class IV : Dirty Purulent inflammation (abscess) Pre-operative perforation of GI, GU, biliary or respiratory tract Penetrating trauma > 4 hrs Existing acute bacterial infection or a perforated viscera is encountered (clean tissue is transected to gain access to pus). Risk of infection: 40%

Signs of Infection The cardinal points of acute inflammation Calor Rubor Dolor Tumour Functio Laesa

Signs of Infection Patient may be systemically unwell ↑ Temp Tachycardic Hypotension Wound breakdown Wound discharge Warm peripheries Septic shock

Prevention Aseptic technique Good technique Prophylactic antibiotics where appropriate Microbiology input Clean operating theatre Elective surgery Good post op care

Wound Healing Wound healing is a complex and dynamic process of restoring cellular structures and tissue layers There are 3 distinct phases There are various categories of wound healing the ultimate outcome of any healing process is repair of a tissue defect

Wound Healing The types of wound healing: 1° healing Delayed 1° healing 2° healing (Epithelialisation) Even though different categories exist, the interactions of cellular and extracellular constituents are similar.

Primary wound healing Also known as “healing by primary intention” Think of a typical surgical wound: the wound eges are approximated Minimal number of cellular constituents die Results in a small line of scar tissue Minimizes the need for granulation tissue so scarring is minimized

The importance of good… Technique Choice of suture Choice of needle Training Instruments Antibiotics Aftercare

Delayed Primary healing Occurs if wound egdes are not approximated immediately May be desired in contaminated wounds By day 4: phagocytosis of contaminated tissues has occurred Usually wound is closed surgically at this stage If contamination is present still : chronic inflammation ensues leading to prominent scar eventually

Secondary Healing Also called healing by secondary intention A full thickness wound is allowed to heal by itself: there is no approximation of wound edges Large amounts of granulation tissue formed Wound eventually very contracted Takes much longer to heal

Epithelialization Epithelization is the process by which epithelial cells migrate and replicate via mitosis and traverse the wound Occurs by one of 2 mechanisms Common in the healing of ulcers and erosions

Epithelialization: Mechanisms Mechanism 1 If basement membrane is intact ie some dermis or dermal appendages remain Epithelialization occurs by epithelial cells migrating upwards

Epithelialization: Mechanisms Mechanism 2 Occurs in a deeper wound A single layer of epithelial cells advance from the wound edges to cover the wound They then stratify so wound cover is complete

Normal Wound Healing There are 3 phases Inflammatory phase: Days 0-4 Proliferative phase : Days 5-21 Remodelling phase: Days 22-60

Wound Healing It can also be classified in 4 stages: Haemostasis Inflammation Granulation Remodelling

Haemostasis Injury causes local bleeding Vasoconstriction is mediated by : Adrenaline Thrombaxane A2 Prostaglandin 2 α

Haemostasis Platelets then adhere to damaged endothelium and discharge ADP Which promotes thrombocyte clumping and “dams” the wound Inflammation is initiated by cytokine release from platelets

Haemostasis α -granules from platelets release: Platelet Derived Growth Factor (PDGF) Platelet factor IV Transforming Growth Factor β Thrombocyte dense bodies release: Histamine Serotonin

Haemostasis PDGF attracts fibroblasts chemotactically Leading to collagen deposition in later stages of wound healing Fibrinogen -> Fibrin Thus providing the structural support for the cellular components of inflammation

Inflammatory Phase Capillary dilatation occurs due to: Histamine Bradykinin Prostaglandins NO This dilatation allows inflammatory cells to reach the wound site

Inflammatory Phase These PMNs or leukocytes have several functions: Scavenge for debris Debride the wound Help to kill bacteria by: -oxidative burst mechanisms -opsonization

Inflammatory Phase Opsonin “ factor which enhances the efficiency of phagocytosis because it is recognized by receptors on leucocytes 2 major opsonins are: Fc fragment of IgG A product of complement, C3b

Inflammatory Phase Monocytes now enter the wound and become macrophages They have numerous functions

Macrophage functions in healing Secretion of numerous enzymes and cytokines Collagenases and elastases To break down injured tissues PDGF, TGF β , IL, TNF To stimulate proliferation of fibroblasts, endothelial and smooth muscle cells

Proliferative Phase Angiogenesis The formation of new blood vessels Formed by endothelial cells becoming new capillaries within the wound bed Angiogenesis stimulated by TNF α

Proliferative Phase Collagen deposition Type III collagen is laid down by fibroblasts Fibroblasts are attracted by TGF β and PDGF Total collagen content increases until day 21

Proliferative Phase Granulation Tissue Is the combination of collagen deposition and angiogenesis

Granulation Tissue Definition: Newly formed connective tissue, often found at the edge or base of ulcers and wounds made up of : capillaries, fibroblasts, myofibroblasts, and inflammatory cells embedded in a mucin rich ground substance during healing

Proliferative Phase Re-epithelialization occurs next: By upward migration of epithelial cells if BM is intact Or from wound edges

Remodelling Phase Fibroblasts become myofibroblasts And wound begins to contract Can contract 0.75mm per day Can over contract however Contraction allows wound to become smaller A large wound can contract by up to 40-80%

Remodelling Phase Type III collagen is degraded And replaced with Type I Water is removed from the scar, allowing collagen to cross-link Wound vascularity decreases Collagen cross linkage allows: Increased scar strength Scar contracture Decreased scar thickness

Wound Strength During phase 1 and 2 (inflammatory and proliferative phases) Wounds have very little strength During remodelling: Wounds rapidly gain strength @ 6 weeks: wound is 50% of final strength @12 months: wound is maximal strength: but this is only 75% of pre-injury tissue strength

Abnormal Scars Hypertrophic Scars Keloid Scars

Hypertrophic Scars Raised, red and thickened Limited to boundaries of scar Occurs shortly after injury Common on anterior chest and deltoids Regresses over time Related to wound tension and prolonged inflammatory phase of healing

Hypertrophic Scars Treatment: Surgical excision Intralesional Triamcenelone acetate injection

Hypertrophic Scars No racial or familial preponderance Electron microscopy: flattened collagen bundles parallel in orientation

Keloid Scars Raised, red and thickened scar Extends beyond original scar boundary Occurs months after injury Does not regress Commoner in darker skinned people Familial tendency ? Autoimmune phenomenon Worsened by surgery and in pregnancy Regresses post menopause

Keloid scar Treatment: Surgical excision : caveat- recurrence = 65% Compression treatment CO2 lasers Cryotherapy

Factors influencing scarring These can be broken down into: Patient factors Surgical factors

Patient Factors Age Elderly scar well -? 2° wrinkles Skin type Celtics : hypertrophic scar tendency Dark skinned: keloid scars

Patient Factors Anatomic region Midline Deltoid region Sternotomy post CABG

Patient Factors Patient morbidity Nutritional state Diabetes Wound infections

Patient Factors Local tissue Oedema Previous radiotherapy Vascular insufficiency

Surgical factors Atraumatic skin handling Eversion of wound edges Inversion places keratinised epidermis between the healing surfaces = delayed healing Tension free closure Clean and healthy wound edges

Surgical factors Scar orientation Parallel to lines of relaxed skin tension Langers lines Suture tension “ Thou shall not commit tension” Over-tight: pressure necrosis Under-tight: wound gaping and widened scar

Acute Inflammation Definition The cellular and vascular response to injury Short in duration Has cellular and chemical components

Acute Inflammation: Causes Injury by: Pathogens Bacteria, viruses, parasites Chemical agents Acids, alkalis Physical agents Heat, trauma (surgery), radiation Tissue death Infarction

Stages of Acute Inflammation Dilatation of local capillaries ⁭ endothelial permeability Leakage of protein-rich fluid into interstitial space – including fibrinogen Fibrinogen -> fibrin Margination of leukocytes to peripheries of capillaries Mostly neutrophils

Stages of Acute Inflammation Acute Inflammation is mediated by: Chemicals: interleukins and histamine Proteins: complement cascade

Complement Cascade Component of innate immune system Cascade of proteins Resulting in formation of Membrane-Attack-Complex (MAC) which can Destroy invading bacteria Recruit other cells ie neutrophils Can also act as opsonins: enhancing phagocytosis

Complement Cascade 2 main activating arms of CC: Classic pathway: consists of antigen-antibody complexes Alternative pathway: activated directly by contact with micro-organisms

Acute Inflammation: Neutrophils The role of the Neutrophil First cellular component to appear Attracted by inflammatory mediators By chemotaxis They can move: margination in blood vessels – by adhering to vascular endothelium: roll between endothelial cells: emigrate to interstitium

Acute Inflammation: Neutrophils Function: Phagocytosis of micro-organisms With lysosomal free radical degradation of pathogens

Chemical messengers in AI These allow cells to communicate with each other and mediate the immune response

Chemical messengers in AI Chemokines Cause direct migration of target cells to site of release Cytokines Soluble, biologically active molecules secreted by cells which have a variety of effects on the target cells

Cytokines: Examples IL-1: neutrophil adhesion and vascular adhesion molecules IL-2: proliferation of B cells and NK cells TNF: causes fever and promotes inflammation IFN: activates macrophages Histamine: vasodilation and ⁭ permeability

Effects of AI: beneficial Dilution of bacterial toxin Defence mechanisms are brought to the pathogen neutrophils;: phagocytosis Complement: cell lysis Antibodies Drug delivery

Effects of AI: beneficial Drainage to LNs: immune response stimulated Fibrin traps the pathogen in place so it can be attacked

Effects of AI: non beneficial Destruction of normal tissue: RA Lethal swelling in certain parts of the body ie epiglottitis Hypersensitivity reactions Asthma Anaphylaxis

Outcomes of Acute Inflammation Resolution Tissues restored to normal Pus/abscess Organization Tissues replaced by granulation tissues Chronic Inflammation If causative agent not removed

Chronic Inflammation Definition Tissue response to persistent injury Long in duration Cellular components differ from acute inflammation

Chronic Inflammation Causes Foreign bodies: ie sutures Bacteria: ie TB Chronic abscess: ie osteomyelitis Transplant: ie chronic rejection IBD Progression from AI

Chronic Inflammation Key points Histological pattern not as predictable as acute inflammation There may be areas of acute inflammation occurring simultaneously Granulation tissue and fibrosis may both be present: indicating the tissues attempts at repair

Chronic Inflammation Lymphocytes predominate Macrophages present too In granulomatous inflammation they fuse forming multinucleate Langhans giant cells Plasma cells are also present

Chronic Inflammation Macrophages Derived from monocytes Phagocytosis and killing of pathogens by lysosomes Antigen presentation Langhans giant cell formation

Chronic Inflammation: Effects Secondary infection ie chronic epithelial injury Scarring Resolution: restoration of normality Local lymphadenopathy

Surgical Incisions Gridiron: appendix

Surgical Incisions Lanz: appendix

Surgical Incisions Nephrectomy/ loin

Surgical Incisions Inguinal : hernia, orchidectomy (for Ca) not for torsion

Surgical Incisions Midline sternotomy

Surgical Incisions Mercedes Benz/Chevron

Surgical Incisions Midline laparotomy

Surgical Incisions Rutherford Morrison : renal transplant

Surgical Incisions Lap appendix

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