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Wound Healing Phases

Editor: Patrick M. Zito Updated: 6/12/2023 7:57:01 PM

Introduction

Wound healing is a natural physiological reaction to tissue injury. However, wound healing is not a simple phenomenon but involves a complex interplay between numerous cell types, cytokines, mediators, and the vascular system. The cascade of initial vasoconstriction of blood vessels and platelet aggregation is designed to stop bleeding. This is followed by an influx of a variety of inflammatory cells, starting with the neutrophil. These inflammatory cells, in turn, release a variety of mediators and cytokines to promote angiogenesis, thrombosis, and reepithelialization. The fibroblasts, in turn, lay down extracellular components which will serve as scaffolding.[1]

The inflammatory phase is characterized by hemostasis, chemotaxis, and increased vascular permeability, limiting further damage, closing the wound, removing cellular debris and bacteria, and fostering cellular migration. The duration of the inflammatory stage usually lasts several days.[2]

The proliferative phase is characterized by the formation of granulation tissue, reepithelialization, and neovascularization. This phase can last several weeks.

The maturation and remodeling phase is where the wound achieves maximum strength as it matures.[3]

Function

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Function

When an injury occurs, the initial phase is always an outpouring of lymphatic fluid and blood. It is during this process that adequate hemostasis is achieved. Both the extrinsic and intrinsic coagulation pathways are activated and play a role in stopping blood loss. Aggregation of platelets follows the arterial vasoconstriction to the damaged endothelial lining. A release of adenosine 5´ diphosphate (ADP) results in the clumping of platelets and initiates the process of thrombosis. This vasoconstriction is a short-lived process that is soon followed by vasodilation, which allows the influx of white cells and more thrombocytes.

The inflammatory phase begins with hemostasis and chemotaxis. Both the white cells and thrombocytes speed up the inflammatory process by releasing more mediators and cytokines. Besides the platelet-derived growth factor, other factors promote collagen degradation, the transformation of fibroblasts, the growth of new vessels, and re-epithelialization. All of the processes occur at the same time but in a synchronized fashion. Mediators like serotonin and histamine are released from platelets and increase cellular permeability. The platelet-derived growth factor attracts fibroblasts and, along with transforming growth factor, enhances the division and multiplication of fibroblasts. The fibroblasts, in turn, synthesize collagen.

Inflammatory cells, such as neutrophils, monocytes, and endothelial cells, adhere to a fibrin scaffold formed by platelet activation. The neutrophils enable phagocytosis of cellular debris and bacteria, allowing for decontamination of the wound.[4]

The proliferative or granulation phase does not occur at a discrete time, but is ongoing all the time in the background.

By days 5 through 7, the fibroblasts have started to lay down new collagen and glycosaminoglycans. These proteoglycans form the core of the wound and help stabilize the wound. Then, reepithelialization starts to occur with the migration of cells from the wound periphery and adjacent edges. Initially, only a thin superficial layer of epithelial cells is laid down, but a thicker and more durable layer of cells will bridge the wound over time. Next, neovascularization occurs through both angiogenesis, forming new blood vessels from existing vessels, and vasculogenesis, which is the formation of new vessels from endothelial progenitor cells (EPCs). Once collagen fibers have been laid down on the fibrin framework, the wound starts to mature. The wound also begins to contract and is facilitated by continued deposition of fibroblasts and myofibroblasts.

The maturational or remodeling phase starts around week 3 and can last up to 12 months. The excess collagen degrades, and wound contraction also begins to peak around week 3. Wound contraction occurs to a much greater extent in secondary healing than in primary healing. The maximal tensile strength of the incision wound occurs after about 11 to 14 weeks. The ultimate resulting scar will never have 100% of the original strength of the wound and only about 80% of the tensile strength.[3]

Issues of Concern

Wounds generally heal in 4 to 6 weeks. Chronic wounds are those that fail to heal within this timeframe. 

Many factors can lead to impaired healing. The primary factors are hypoxia, bacterial colonization, ischemia, reperfusion injury, altered cellular response, and collagen synthesis defects. These may result from a systemic illness, such as diabetes, or chronic conditions, such as smoking or malnutrition. Local factors that can impair wound healing are pressure, tissue edema, hypoxia, infection, maceration, and dehydration. 

Bacterial biofilm, a slime created by a bacterial community to protect against host defenses and allow bacterial proliferation, is another inhibitory factor of wound healing. Biofilm can produce low oxygen, low pH environment for the wound. This film also can create a physical barrier that prevents cellular migration and prevents antibiotic and antibody penetration.[5]

Clinical Significance

Clinical considerations in wound management include preventing and controlling infection and contamination, maintaining adequate moisture, treating edema, and preventing further injury. 

Wounds should be cleansed prior to closure. Wounds can be cleaned with either irrigation or scrubbed and irrigated with a 0.9% saline solution. Alternately, wounds can be scrubbed with pluronic polyols and irrigated with normal saline. Tap water is frequently used by patients to irrigate wounds before seeking out medical attention. The advantage is that copious amounts of irrigant can be rapidly used; however, irrigation pressure may be difficult to control. A study by Mosacati found that infection rates for wounds irrigated with tap water were comparable to those irrigated by a 0.9% saline solution.[6]

Other Issues

Wound dressings should create a moist environment to prevent wound desiccation but allows for absorption of additional exudate. In addition, it should allow for airflow, prevent particulate contamination, and be impermeable to bacteria or microbiota. 

Several techniques are used to reconstruct or surgically repair wounds, the simplest of which is primary closure. Other techniques are closure via secondary intention, negative pressure wound therapy, and grafting.

Wound Healing Controversies and the Future

  • Fetal tissue has been shown to heal without scars, but its clinical role has yet to be determined.
  • Transforming growth factor and several other cytokines all have a role in healing, but when to add or how much of the cytokine is needed for adequate healing is still being debated. 
  • Hyperbaric oxygen can promote healing, but the technique and success rate are not well established.
  • Even though there are many anecdotal reports on honey and wound healing, controlled studies show that the benefits of honey are marginal at best.
  • Finally, medications that can adversely affect healing include anticonvulsants, steroids, antibiotics, angiogenesis inhibitors, and NSAIDs. Drugs known to promote healing include insulin, vitamins, thyroid hormone, and iron.
  • The new frontier for wound healing is the use of stem cells, but there are ethical issues regarding the widespread use of this technology.[7][1]

Enhancing Healthcare Team Outcomes

Current studies on wound healing focus on identifying molecular level target genes that can be enhanced to expedite natural wound healing. The hedgehog signaling pathway has been used in multiple studies due to its role in epithelial-mesenchymal interaction in wound healing. [8] Laser techniques are being explored to enhance cell proliferation and accelerate wound healing.[9][10] A multifaceted approach to wound healing focusing on adequate dressing and local care, nutritional support, and hyperbaric oxygen therapy in severe cases is necessary to ensure proper wound healing in the most difficult of cases. 

References


[1]

Ozgok Kangal MK, Regan JP. Wound Healing. StatPearls. 2024 Jan:():     [PubMed PMID: 30571027]


[2]

Coger V, Million N, Rehbock C, Sures B, Nachev M, Barcikowski S, Wistuba N, Strauß S, Vogt PM. Tissue Concentrations of Zinc, Iron, Copper, and Magnesium During the Phases of Full Thickness Wound Healing in a Rodent Model. Biological trace element research. 2019 Sep:191(1):167-176. doi: 10.1007/s12011-018-1600-y. Epub 2018 Dec 14     [PubMed PMID: 30552609]


[3]

Bowden LG, Byrne HM, Maini PK, Moulton DE. A morphoelastic model for dermal wound closure. Biomechanics and modeling in mechanobiology. 2016 Jun:15(3):663-81. doi: 10.1007/s10237-015-0716-7. Epub 2015 Aug 12     [PubMed PMID: 26264498]


[4]

Ninan N, Thomas S, Grohens Y. Wound healing in urology. Advanced drug delivery reviews. 2015 Mar:82-83():93-105. doi: 10.1016/j.addr.2014.12.002. Epub 2014 Dec 9     [PubMed PMID: 25500273]


[5]

van Koppen CJ, Hartmann RW. Advances in the treatment of chronic wounds: a patent review. Expert opinion on therapeutic patents. 2015:25(8):931-7. doi: 10.1517/13543776.2015.1045879. Epub 2015 Jun 3     [PubMed PMID: 26039457]

Level 3 (low-level) evidence

[6]

Pisarik P. Choosing Tap Water vs. Sterile Saline for Wound Irrigation. American family physician. 2016 Jul 15:94(2):83-4     [PubMed PMID: 27419322]


[7]

Moores J. Vitamin C: a wound healing perspective. British journal of community nursing. 2013 Dec:Suppl():S6, S8-11     [PubMed PMID: 24796079]

Level 3 (low-level) evidence

[8]

Park HJ, Lee J, Kim MJ, Kang TJ, Jeong Y, Um SH, Cho SW. Sonic hedgehog intradermal gene therapy using a biodegradable poly(β-amino esters) nanoparticle to enhance wound healing. Biomaterials. 2012 Dec:33(35):9148-56. doi: 10.1016/j.biomaterials.2012.09.005. Epub 2012 Sep 25     [PubMed PMID: 23018131]

Level 3 (low-level) evidence

[9]

Nilforoushzadeh MA, Kazemikhoo N, Mokmeli S, Zare S, Dahmardehei M, Vaghar Doost R, Momeni M, Ansari F. An Open-Label Study of Low-Level Laser Therapy Followed by Autologous Fibroblast Transplantation for Healing Grade 3 Burn Wounds in Diabetic Patients. Journal of lasers in medical sciences. 2019 Fall:10(Suppl 1):S7-S12. doi: 10.15171/jlms.2019.S2. Epub 2019 Dec 1     [PubMed PMID: 32021666]


[10]

Reddy SP, Koduganti RR, Panthula VR, Surya Prasanna J, Gireddy H, Dasari R, Ambati M, Chandra G B. Efficacy of Low-level Laser Therapy, Hyaluronic Acid Gel, and Herbal Gel as Adjunctive Tools in Gingivectomy Wound Healing: A Randomized Comparative Clinical and Histological Study. Cureus. 2019 Dec 21:11(12):e6438. doi: 10.7759/cureus.6438. Epub 2019 Dec 21     [PubMed PMID: 31993275]

Level 2 (mid-level) evidence