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20.2: Basic Concepts Related to Wounds

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    Phases of Wound Healing

    When skin is injured, there are four phases of wound healing that take place: hemostasis, inflammatory, proliferative, and maturation.[1] See Figure \(\PageIndex{1}\)[2] for an illustration of the phases of wound healing.

    Illustration showing phases of wound healing, with labels
    Figure \(\PageIndex{1}\): Phases of Wound Healing

    To illustrate the phases of wound healing, imagine that you accidentally cut your finger with a knife as you were slicing an apple. Immediately after the injury occurs, blood vessels constrict and clotting factors are activated. This is referred to as the hemostasis phase. Clotting factors form clots that stop the bleeding and act as a barrier to prevent bacterial contamination. Platelets release growth factors that alert various cells to start the repair process at the wound location. The hemostasis phase lasts up to 60 minutes, depending on the severity of the injury.[3],[4]

    After the hemostasis phase, the inflammatory phase begins. Vasodilation occurs so that white blood cells in the bloodstream can move into the wound to start cleaning the wound bed. The inflammatory process appears to the observer as edema (swelling), erythema (redness), and exudate. Exudate is fluid that oozes out of a wound, also commonly called pus.[5],[6]

    The proliferative phase begins within a few days after the injury and includes four important processes: epithelialization, angiogenesis, collagen formation, and contraction. Epithelialization refers to the development of new epidermis and granulation tissue. Granulation tissue is new connective tissue with new, fragile, thin-walled capillaries. Collagen is formed to provide strength and integrity to the wound. At the end of the proliferation phase, the wound begins to contract in size.[7],[8]

    Capillaries begin to develop within the wound 24 hours after injury during a process called angiogenesis. These capillaries bring more oxygen and nutrients to the wound for healing. When performing dressing changes, it is essential for the nurse to protect this granulation tissue and the associated new capillaries. Healthy granulation tissue appears pink due to the new capillary formation. It is also moist, painless to the touch, and may appear “bumpy.” Conversely, unhealthy granulation tissue is dark red and painful. It bleeds easily with minimal contact and may be covered by shiny white or yellow fibrous tissue referred to as biofilm that must be removed because it impedes healing. Unhealthy granulation tissue is often caused by an infection, so wound cultures should be obtained when infection is suspected. The provider can then prescribe appropriate antibiotic treatment based on the culture results.[9]

    During the maturation phase, collagen continues to be created to strengthen the wound. Collagen contributes strength to the wound to prevent it from reopening. A wound typically heals within 4-5 weeks and often leaves behind a scar. The scar tissue is initially firm, red, and slightly raised from the excess collagen deposition. Over time, the scar begins to soften, flatten, and become pale in about nine months.[10]

    Types of Wound Healing

    There are three types of wound healing: primary intention, secondary intention, and tertiary intention. Healing by primary intention means that the wound is sutured, stapled, glued, or otherwise closed so the wound heals beneath the closure. This type of healing occurs with clean-edged lacerations or surgical incisions, and the closed edges are referred to as approximated. See Figure \(\PageIndex{2}\)[11] for an image of a surgical wound healing by primary intention.

    Photo closeup of stiches healing on a person's stomach
    Figure \(\PageIndex{2}\): Primary Intention Wound Healing

    Secondary intention occurs when the edges of a wound cannot be approximated (brought together), so the wound fills in from the bottom up by the production of granulation tissue. Examples of wounds that heal by secondary intention are pressure injuries and chainsaw injuries. Wounds that heal by secondary infection are at higher risk for infection and must be protected from contamination. See Figure \(\PageIndex{3}\)[12] for an image of a wound healing by secondary intention.

    Photo showing a wound on the forearm healing by secondary intention
    Figure \(\PageIndex{3}\): Secondary Intention Wound Healing

    Tertiary intention refers to a wound that has had to remain open or has been reopened, often due to severe infection. The wound is typically closed at a later date when infection has resolved. Wounds that heal by secondary and tertiary intention have delayed healing times and increased scar tissue.

    Wound Closures

    Lacerations and surgical wounds are typically closed with sutures, staples, or dermabond to facilitate healing by primary intention. See Figure \(\PageIndex{4}\)[13] for an image of sutures, Figure \(\PageIndex{5}\)[14] for an image of staples, and Figure \(\PageIndex{6}\)[15] for an image of a wound closed with dermabond, a type of sterile surgical glue. Based on agency policy, the nurse may remove sutures and staples based on a provider order. See Figure \(\PageIndex{7}\)[16] for an image of a disposable staple remover. See the checklists in the subsections later in this chapter for procedures related to surgical and staple removal.

    Photo showing closeup of healing sutures
    Figure \(\PageIndex{4}\): Sutures
    Photo showing a stapled, healing wound
    Figure \(\PageIndex{5}\): Staples
    Photo showing Dermanbond on a healing wound
    Figure \(\PageIndex{6}\): Dermabond
    Photo showing closeup of a staple remover
    Figure \(\PageIndex{7}\): Staple Remover

    Common Types of Wounds

    There are several different types of wounds. It is important to understand different types of wounds when providing wound care because each type of wound has different characteristics and treatments. Additionally, treatments that may be helpful for one type of wound can be harmful for another type. Common types of wounds include skin tears, venous ulcers, arterial ulcers, diabetic foot wounds, and pressure injuries.[17]

    Skin Tears

    Skin tears are wounds caused by mechanical forces such as shear, friction, or blunt force. They typically occur in the fragile, nonelastic skin of older adults or in patients undergoing long-term corticosteroid therapy. Skin tears can be caused by the simple mechanical force used to remove an adhesive bandage or from friction as the skin brushes against a surface. Skin tears occur in the epidermis and dermis but do not extend through the subcutaneous layer. The wound bases of skin tears are typically fragile and bleed easily.[18]

    Venous Ulcers

    Venous ulcers are caused by lack of blood return to the heart causing pooling of fluid in the veins of the lower legs. The resulting elevated hydrostatic pressure in the veins causes fluid to seep out, macerate the skin, and cause venous ulcerations. Maceration refers to the softening and wasting away of skin due to excess fluid. Venous ulcers typically occur on the medial lower leg and have irregular edges due to the maceration. There is often a dark-colored discoloration of the lower legs, due to blood pooling and leakage of iron into the skin called hemosiderin staining. For venous ulcers to heal, compression dressings must be used, along with multilayer bandage systems, to control edema and absorb large amounts of drainage.[19] See Figure \(\PageIndex{8}\)[20] for an image of a venous ulcer.

    Photo showing closeup of skin damage on lower leg due to venous ulcer
    Figure \(\PageIndex{8}\): Venous Ulcer

    Arterial Ulcers

    Arterial ulcers are caused by lack of blood flow and oxygenation to tissues. They typically occur in the distal areas of the body such as the feet, heels, and toes. Arterial ulcers have well-defined borders with a “punched out” appearance where there is a localized lack of blood flow. They are typically painful due to the lack of oxygenation to the area. The wound base may become necrotic (black) due to tissue death from ischemia. Wound dressings must maintain a moist environment, and treatment must include the removal of necrotic tissue. In severe arterial ulcers, vascular surgery may be required to reestablish blood supply to the area.[21] See Figure \(\PageIndex{9}\)[22] for an image of an arterial ulcer on a patient’s foot.

    Photo showing arterial ulcer on top of a foot
    Figure \(\PageIndex{9}\): Arterial Ulcer

    Diabetic Ulcers

    Diabetic ulcers are also called neuropathic ulcers because peripheral neuropathy is commonly present in patients with diabetes. Peripheral neuropathy is a medical condition that causes decreased sensation of pain and pressure, especially in the lower extremities. Diabetic ulcers typically develop on the plantar aspect of the feet and toes of a patient with diabetes due to lack of sensation of pressure or injury. See Figure \(\PageIndex{10}\)[23] for an image of a diabetic ulcer. Wound healing is compromised in patients with diabetes due to the disease process. In addition, there is a higher risk of developing an infection that can reach the bone requiring amputation of the area. To prevent diabetic ulcers from occurring, it is vital for nurses to teach meticulous foot care to patients with diabetes and encourage the use of well-fitting shoes.[24]

    Photo showing closeup of diabetic ulcer on bottom of patient's foot
    Figure \(\PageIndex{10}\): Diabetic Ulcer

    Pressure Injuries

    Pressure injuries are defined as “localized damage to the skin or underlying soft tissue, usually over a bony prominence, as a result of intense and prolonged pressure in combination with shear.”[25] Shear occurs when tissue layers move over the top of each other, causing blood vessels to stretch and break as they pass through the subcutaneous tissue. For example, when a patient slides down in bed, the outer skin remains immobile because it remains attached to the sheets due to friction, but deeper tissue attached to the bone moves as the patient slides down. This opposing movement of the outer layer of skin and the underlying tissues causes the capillaries to stretch and tear, which then impacts the blood flow and oxygenation of the surrounding tissues.

    Braden Scale

    Several factors place a patient at risk for developing pressure injuries, including nutrition, mobility, sensation, and moisture. The Braden Scale is a tool commonly used in health care to provide an objective assessment of a patient’s risk for developing pressure injuries. See Figure \(\PageIndex{11}\)[26] for an image of a Braden Scale. The six risk factors included on the Braden Scale are sensory perception, moisture, activity, mobility, nutrition, and friction/shear, and these factors are rated on a scale from 1-4 with 1 being “completely limited” to 4 being “no impairment.” The scores from the six categories are added, and the total score indicates a patient’s risk for developing a pressure injury. Ranges of scores indicate mild risk for scores 15-19, moderate risk for scores 13-14, high risk for scores 10-12, and severe risk for scores less than 9. Nurses create care plans using these scores to plan interventions that prevent or treat pressure injuries.

    For more information about using the Braden Scale, go to the “Integumentary” chapter of the Open RN Nursing Fundamentals textbook.

    Photo showing the Braden Scale for predicting pressure sore risk
    Figure \(\PageIndex{11}\): Braden Scale. Used under Fair Use.
    Staging

    Pressure injuries commonly occur on the sacrum, heels, ischial tuberosity, and coccyx. The 2016 National Pressure Ulcer Advisory Panel (NPUAP) Pressure Injury Staging System now uses the term “pressure injury” instead of pressure ulcer because an injury can occur without an ulcer present. Pressure injuries are staged from 1 through 4 based on the extent of tissue damage. For example, Stage 1 pressure injuries have reddened but intact skin, and Stage 4 pressure injuries have deep, open ulcers affecting underlying tissue and structures such as muscles, ligaments, and tendons. See Figure \(\PageIndex{12}\)[27] for an image of the four stages of pressure injuries.[28] The NPUAP’s definitions of the four stages of pressure injuries are described below:

    • Stage 1 pressure injuries are intact skin with a localized area of nonblanchable erythema where prolonged pressure has occurred. Nonblanchable erythema is a medical term used to describe skin redness that does not turn white when pressed.
    • Stage 2 pressure injuries are partial-thickness loss of skin with exposed dermis. The wound bed is viable and may appear like an intact or ruptured blister. Stage 2 pressure injuries heal by reepithelialization and not by granulation tissue formation.[29]
    • Stage 3 pressure injuries are full-thickness tissue loss in which fat is visible, but cartilage, tendon, ligament, muscle, and bone are not exposed. The depth of tissue damage varies by anatomical location. Undermining and tunneling may occur in Stage 3 and 4 pressure injuries. Undermining occurs when the tissue under the wound edges becomes eroded, resulting in a pocket beneath the skin at the wound’s edge. Tunneling refers to passageways underneath the surface of the skin that extend from a wound and can take twists and turns. Slough and eschar may also be present in Stage 3 and 4 pressure injuries. Slough is an inflammatory exudate that is usually light yellow, soft, and moist. Eschar is dark brown/black, dry, thick, and leathery dead tissue. See Figure \(\PageIndex{13}\) [30] for an image of eschar in the center of the wound. If slough or eschar obscures the wound so that tissue loss cannot be assessed, the pressure injury is referred to as unstageable.[31] In most wounds, slough and eschar must be removed by debridement for healing to occur.
    • Stage 4 pressure injuries are full-thickness tissue loss like Stage 3 pressure injuries, but also have exposed cartilage, tendon, ligament, muscle, or bone. Osteomyelitis (bone infection) may be present.[32]
    Photo showing four stages of pressure wounds
    Figure \(\PageIndex{12}\): Stages of Pressure Wounds
    Photo showing slough on a wound
    Figure \(\PageIndex{13}\): Eschar
    Video Review of Pressure Injuries[33]

    Factors Affecting Wound Healing

    Multiple factors affect a wound’s ability to heal and are referred to as local and systemic factors. Local factors refer to factors that directly affect the wound, whereas systemic factors refer to the overall health of the patient and their ability to heal. Local factors include localized blood flow and oxygenation of the tissue, the presence of infection or a foreign body, and venous sufficiency. Venous insufficiency is a medical condition where the veins in the legs do not adequately send blood back to the heart, resulting in a pooling of fluids in the legs.[34]

    Systemic factors that affect a patient’s ability to heal include nutrition, mobility, stress, diabetes, age, obesity, medications, alcohol use, and smoking.[35] When a nurse is caring for a patient with a wound that is not healing as anticipated, it is important to further assess for the potential impact of these factors:

    • Nutrition. Nutritional deficiencies can have a profound impact on healing and must be addressed for chronic wounds to heal. Protein is one of the most important nutritional factors affecting wound healing. For example, in patients with pressure injuries, 30 to 35 kcal/kg of calorie intake with 1.25 to 1.5g/kg of protein and micronutrients supplementation is recommended daily.[36] In addition, vitamin C and zinc deficiency have many roles in wound healing. It is important to collaborate with a dietician to identify and manage nutritional deficiencies when a patient is experiencing poor wound healing.[37]
    • Stress. Stress causes an impaired immune response that results in delayed wound healing. Although a patient cannot necessarily control the amount of stress in their life, it is possible to control one’s reaction to stress with healthy coping mechanisms. The nurse can help educate the patient about healthy coping strategies.
    • Diabetes. Diabetes causes delayed wound healing due to many factors such as neuropathy, atherosclerosis (a buildup of plaque that obstructs blood flow in the arteries resulting in decreased oxygenation of tissues), a decreased host immune resistance, and increased risk for infection.[38] Read more about neuropathy and diabetic ulcers under the “Types of Wounds” section. Nurses provide vital patient education to patients with diabetes to effectively manage the disease process for improved wound healing.
    • Age. Older adults have an altered inflammatory response that can impair wound healing. Nurses can educate patients about the importance of exercise for improved wound healing in older adults.[39]
    • Obesity. Obese individuals frequently have wound complications, including infection, dehiscence, hematoma formation, pressure injuries, and venous injuries. Nurses can educate patients about healthy lifestyle choices to reduce obesity in patients with chronic wounds.[40]
    • Medications. Medications such as corticosteroids impair wound healing due to reduced formation of granulation tissue.[41] When assessing a chronic wound that is not healing as expected, it is important to consider the side effects of the patient’s medications.
    • Alcohol consumption. Research shows that exposure to alcohol impairs wound healing and increases the incidence of infection.[42] Patients with impaired healing of chronic wounds should be educated to avoid alcohol consumption.
    • Smoking. Smoking impacts the inflammatory phase of the wound healing process, resulting in poor wound healing and an increased risk of infection.[43] Patients who smoke should be encouraged to stop smoking.

    Lab Values Affecting Wound Healing

    When a chronic wound is not healing as expected, laboratory test results may provide additional clues regarding the causes of the delayed healing. See Table \(\PageIndex{1}\) for lab results that offer clues to systemic issues causing delayed wound healing.[44]

    Table \(\PageIndex{1}\) Lab Values Associated with Delayed Wound Healing[45]
    Abnormal Lab Value Rationale
    Low hemoglobin Low hemoglobin indicates less oxygen is transported to the wound site.
    Elevated white blood cells (WBC) Increased WBC indicates infection is occurring.
    Low platelets Platelets are important during the proliferative phase in the creation of granulation tissue and angiogenesis.[46]
    Low albumin Low albumin indicates decreased protein levels. Protein is required for effective wound healing.
    Elevated blood glucose or hemoglobin A1C Elevated blood glucose and hemoglobin A1C levels indicate poor management of diabetes mellitus, a disease that impacts wound healing.
    Elevated serum BUN and creatinine BUN and creatinine levels are indicators of kidney function, with elevated levels indicating worsening kidney function. Elevated BUN (blood urea nitrogen) levels impact wound healing.
    Positive wound culture Positive wound cultures indicate an infection is present and provide additional information including the type and number of bacteria present, as well as identifying antibiotics to which the bacteria is susceptible. The nurse reviews this information when administering antibiotics to ensure the prescribed therapy is effective for the type of bacteria present.

    Wound Complications

    In addition to delayed wound healing, several other complications can occur. Three common complications are the development of a hematoma, infection, or dehiscence. These complications should be immediately reported to the health care provider.

    Hematoma

    A hematoma is an area of blood that collects outside of the larger blood vessels. A hematoma is more severe than ecchymosis (bruising) that occurs when small veins and capillaries under the skin break. The development of a hematoma at a surgical site can lead to infection and incisional dehiscence.[47] See Figure \(\PageIndex{14}\)[48] for an image of a hematoma.

    Photo showing hematoma on ankle and foot of person
    Figure \(\PageIndex{14}\): Hematoma

    Infection

    A break in the skin allows bacteria to enter and begin to multiply. Microbial contamination of wounds can progress from localized infection to systemic infection, sepsis, and subsequent life- and limb-threatening infection. Signs of a localized wound infection include redness, warmth, and tenderness around the wound. Purulent or malodorous drainage may also be present. Signs that a systemic infection is developing and requires urgent medical management include the following:[49]

    • Fever over 101 F (38 C)
    • Overall malaise (lack of energy and not feeling well)
    • Change in level of consciousness/increased confusion
    • Increasing or continual pain in the wound
    • Expanding redness or swelling around the wound
    • Loss of movement or function of the wounded area

    Dehiscence

    Dehiscence refers to the separation of the edges of a surgical wound. A dehisced wound can appear fully open where the tissue underneath is visible, or it can be partial where just a portion of the wound has torn open. Wound dehiscence is always a risk in a surgical wound, but the risk increases if the patient is obese, smokes, or has other health conditions, such as diabetes, that impact wound healing. Additionally, the location of the wound and the amount of physical activity in that area also increase the chances of wound dehiscence.[50] See Figure \(\PageIndex{15}\)[51] for an image of dehiscence in an abdominal surgical wound in a 50-year-old obese female with a history of smoking and malnutrition.

    Wound dehiscence can occur suddenly, especially in abdominal wounds when the patient is coughing or straining. Evisceration is a rare but severe surgical complication when dehiscence occurs and the abdominal organs protrude out of the incision. Signs of impending dehiscence include redness around the wound margins and increasing drainage from the incision. The wound will also likely become increasingly painful. Suture breakage can be a sign that the wound has minor dehiscence or is about to dehisce.[52]

    To prevent wound dehiscence, surgical patients must follow all post-op instructions carefully. The patient must move carefully and protect the skin from being pulled around the wound site. They should also avoid tensing the muscles surrounding the wound and avoid heavy lifting as advised.[53]

    Photo showing dehiscence on abdominal wound
    Figure \(\PageIndex{15}\): Dehiscence
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    4. This work is a derivative of StatPearls by Grubbs and Mannah and is licensed under CC BY 4.0↵
    5. This work is a derivative of Clinical Procedures for Safer Patient Care by British Columbia Institute of Technology and is licensed under CC BY 4.0.
    6. This work is a derivative of StatPearls by Grubbs and Mannah and is licensed under CC BY 4.0
    7. This work is a derivative of Clinical Procedures for Safer Patient Care by British Columbia Institute of Technology and is licensed under CC BY 4.0.
    8. This work is a derivative of StatPearls by Grubbs and Mannah and is licensed under CC BY 4.0
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