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Gingivectomy

A gingivectomy is a periodontal surgical procedure that involves the excision of excess or diseased gingival (gum) tissue to eliminate suprabony periodontal pockets, treat gingival enlargements, or correct aesthetic concerns such as a "gummy smile," without involving underlying bone defects. The gingiva consists of free and attached portions that form a protective barrier around teeth; periodontal pockets arise when this tissue becomes inflamed or hypertrophied due to factors like plaque accumulation, altered passive eruption, genetic predisposition, or drug-induced hyperplasia, creating pseudopockets that hinder hygiene and promote infection. The procedure is indicated primarily for conditions involving thick, fibrous gingival walls with no osseous involvement, such as residual pocketing after non-surgical therapy, suprabony pockets, or localized gingival overgrowth that impairs oral function or esthetics. It is particularly useful in patients with firm pocket walls where preservation of attached gingiva is feasible, though it is contraindicated in cases requiring bone access, with narrow keratinized tissue bands, high bleeding risk, or where the procedure would cause significant aesthetic compromise. Historically, gingivectomy emerged as a foundational resective approach in the early 20th century for removing "diseased" gingiva, evolving from radical pocket elimination techniques to more conservative methods integrated with modern periodontal care. Gingivectomy effectively manages soft tissue issues and reduces pocket depths, though it does not address intrabony defects or prevent recurrence if underlying etiologies like plaque persist, often necessitating adjunctive therapies for long-term success.

Overview

Definition and Purpose

Gingivectomy is a surgical procedure involving the excision of gingival tissue to remove diseased, infected, or excessively hypertrophic portions of the gums, thereby eliminating the soft tissue wall of periodontal pockets. This technique is particularly indicated for suprabony pockets where the gingival tissue is fibrous and thick without underlying osseous defects, allowing access to root surfaces for debridement and healing. The term "gingivectomy" originates from the Latin word gingiva, meaning "gum," combined with the Greek suffix -ectomy, denoting surgical removal or excision. Its primary purposes in periodontal therapy encompass reducing pocket depth to prevent further bacterial accumulation, enhancing oral hygiene by creating a more accessible gingival contour, and preparing the area for restorative dental procedures such as crown placement. Additionally, it addresses aesthetic concerns by reshaping overgrown or uneven gum lines, often associated with conditions like gingival enlargement or altered passive eruption. Gingivectomy, first described by Pierre Fauchard in 1742, has evolved into a refined component of modern periodontal surgery, with the term coined by H.P. Pickerill in 1912 and its foundational descriptions emerging in early 20th-century dental literature as a method for pocket elimination and tissue recontouring. In the context of broader periodontal disease management, it serves as a targeted intervention to resolve localized gingival issues following initial non-surgical therapies.

Relevant Anatomy and Physiology

The gingiva, or gums, forms the soft tissue covering of the alveolar processes of the jaws and surrounds the necks of the teeth, serving as a protective barrier against mechanical and microbial insults. It is anatomically divided into the free gingiva, also known as the marginal gingiva, which is the unattached coronal portion forming a collar around the tooth and enclosing the gingival sulcus with a normal depth of 1-3 mm; the attached gingiva, which is firmly bound to the underlying periosteum and tooth cementum via connective tissue fibers, providing stability during mastication; and the interdental papilla, the triangular fill of the interproximal spaces that prevents food impaction and maintains tooth alignment. This differentiation between marginal and attached gingiva is crucial, as the free gingiva is more mobile and susceptible to inflammation, while the attached portion exhibits a stippled surface due to its dense collagenous structure. Periodontal pocket formation arises from chronic inflammation driven by bacterial plaque accumulation in the gingival sulcus, leading to progressive apical migration of the junctional epithelium and deepening of the sulcus beyond its physiological depth. Suprabony pockets develop when the pocket base is coronal to the alveolar bone crest, often associated with horizontal bone loss, whereas infrabony pockets form with the base apical to the bone crest, typically featuring angular defects that influence treatment approaches. The inflammatory cascade begins with plaque-induced cytokine release, causing edema, vascular permeability, and enzymatic degradation of connective tissue, which separates the gingiva from the tooth and bone, exacerbating pocket depth and facilitating further bacterial colonization. The gingiva receives its blood supply primarily from the supraperiosteal plexus derived from branches of the maxillary and mandibular arteries, supplemented by vessels from the periodontal ligament and alveolar bone, ensuring robust nutrient delivery and rapid response to injury. Innervation is provided by the trigeminal nerve branches, with the superior alveolar nerves supplying the maxillary gingiva and the inferior alveolar nerve innervating the mandibular gingiva, conveying sensory fibers for pain, temperature, and pressure while lacking parasympathetic innervation. Epithelial attachment occurs via the junctional epithelium, a specialized non-keratinized layer 10-30 cells thick that adheres to the tooth enamel or cementum through hemidesmosomes and a basal lamina, forming a biological seal against bacterial invasion. Following excision, the physiological healing response involves initial epithelial migration from the wound margins to re-establish coverage within 24-48 hours, followed by granulation tissue formation and collagen remodeling by fibroblasts, which reorganizes the extracellular matrix over weeks to restore tensile strength without scarring.

Clinical Indications

Management of Periodontal Pockets

Gingivectomy serves as a targeted resective procedure for eliminating suprabony periodontal pockets, which are deepened gingival sulci located above the alveolar bone crest without underlying osseous defects. These pockets, often fibrous and firm due to chronic inflammation, harbor plaque and calculus, perpetuating periodontal disease. By surgically excising the excess gingival tissue down to the base of the pocket, gingivectomy exposes the root surfaces, enabling thorough scaling and root planing to remove subgingival deposits and promote healing. Clinical selection for gingivectomy in this context requires specific criteria to ensure efficacy and avoid complications. It is indicated for suprabony pockets measuring at least 5 mm in depth that persist despite initial non-surgical therapy, such as scaling and root planing, and adequate oral hygiene maintenance. The absence of infrabony defects or abnormal bony architecture is essential, as confirmed by preoperative radiographs and periodontal charting, to confirm the pockets are purely soft-tissue related. Additionally, sufficient attached keratinized gingiva must be present to maintain periodontal stability post-resection. The primary benefits of gingivectomy for suprabony pockets include enhanced access for patient hygiene and professional instrumentation, thereby reducing bacterial colonization and inflammation. Post-procedure, the transformed gingival sulcus facilitates easier plaque control, minimizing recurrence risk. Evidence from clinical cases demonstrates significant probing depth reductions; for instance, in a documented orthodontic-related case, depths of 4-5 mm were eliminated entirely, resulting in no remaining suprabony pockets and improved periodontal health indices. Broader reviews indicate typical reductions to physiological sulcus depths of 1-3 mm, with sustained improvements in bleeding on probing and attachment levels when combined with root planing.

Treatment of Gingival Enlargement

Gingival enlargement, also known as gingival hyperplasia or overgrowth, can arise from multiple etiologies, including drug-induced, inflammatory, and hereditary factors. Drug-induced gingival enlargement is commonly associated with medications such as anticonvulsants like phenytoin, immunosuppressants like cyclosporine, and calcium channel blockers like nifedipine, which disrupt collagen metabolism and lead to excessive fibrous tissue accumulation in the gingiva. Inflammatory causes typically stem from chronic plaque accumulation, poor oral hygiene, or local irritants such as orthodontic appliances, resulting in edematous or fibrotic swelling. Hereditary forms, such as gingival fibromatosis, are genetic conditions characterized by progressive, firm gingival overgrowth that may manifest from childhood and affect both arches uniformly or focally. A key distinction in gingival enlargement involves pseudopockets versus true hyperplasia or pockets. Pseudopockets form due to gingival overgrowth that creates apparent probing depths without underlying periodontal attachment loss, often seen in drug-induced or inflammatory cases where excess tissue covers the tooth crown. In contrast, true hyperplasia involves actual proliferation of gingival connective tissue, while true pockets indicate attachment loss from periodontitis, which is not the primary feature here. This differentiation is crucial for treatment planning, as pseudopockets in enlargement respond well to tissue excision without needing osseous intervention. Gingivectomy plays a central role in managing gingival enlargement by surgically excising excess tissue to recontour the gingiva, restore physiologic architecture, prevent progression of overgrowth, and eliminate pseudopockets that harbor plaque. The procedure enhances access for oral hygiene, reduces inflammation, and addresses both localized and generalized presentations, often combined with nonsurgical plaque control for optimal results. In cases where the underlying cause persists, such as ongoing medication use, gingivectomy provides symptomatic relief and functional improvement without altering the etiology. Post-gingivectomy outcomes in gingival enlargement treatment include significant improvements in plaque control and reductions in bleeding on probing. For localized enlargement, such as orthodontic-induced overgrowth in a young patient, gingivectomy can eliminate suprabony pseudopockets and achieve a natural gingival margin within months, enhancing aesthetics and hygiene. In generalized cases, like cyclosporine-related enlargement in renal transplant recipients, the procedure reduces tissue bulk across multiple quadrants, improving mastication and periodontal health, though recurrence may occur if drug therapy continues without vigilant follow-up.

Crown Lengthening for Restorative or Aesthetic Reasons

Crown lengthening through gingivectomy involves the surgical removal of gingival tissue to expose additional tooth structure, thereby increasing the clinical crown height for restorative or aesthetic purposes when sufficient exposure can be achieved without osseous surgery. This approach is suitable for cases of soft tissue excess, such as certain types of altered passive eruption, but restorative indications often require additional bone recontouring to adequately expose subgingival defects while respecting the biologic width. The biologic width is a dimension of approximately 2 mm consisting of the junctional epithelium and connective tissue attachment. Preservation of at least 3 mm of tooth structure apical to the restoration margin (i.e., from margin to alveolar bone) is essential to maintain this biologic width and ensure periodontal health. In restorative contexts, crown lengthening addresses challenges such as subgingival caries, fractures, or decay that extend below the cemento-enamel junction, allowing for adequate access to place restoration margins on sound tooth structure when soft tissue removal alone suffices. By increasing the clinical crown height, the procedure facilitates the creation of a ferrule effect, where at least 1.5-2 mm of tooth structure is encircled by the crown to enhance retention and resistance to fracture, particularly for full-coverage restorations like crowns or bridges. This approach reduces the risk of secondary decay under restorations and improves long-term prognosis, especially in cases of vertical root fractures or extensive decay requiring post-and-core buildups. For aesthetic reasons, crown lengthening corrects excessive gingival display, commonly known as a gummy smile, which occurs when more than 3-4 mm of gingiva is visible during smiling due to altered passive eruption or high lip mobility. The procedure repositions the gingival margin apically to achieve a harmonious tooth-to-gingiva ratio, often exposing 1-2 mm more of the clinical crown per tooth. It is particularly beneficial for patients with a high lip line, where the smile reveals uneven or excessive gingival contours in the anterior region. In such cases, gingivectomy may be combined with orthodontics to intrude over-erupted teeth prior to soft tissue reduction, ensuring stable aesthetic outcomes. Gingival enlargement can contribute to aesthetic concerns by masking tooth structure, though its management is addressed separately. Overall, successful crown lengthening requires precise measurement of the biologic width preoperatively, typically via probing or radiographs, to avoid bone resorption or attachment loss postoperatively. Studies report stable gingival margins and increased crown height of about 1.6 mm at one year following the procedure in aesthetic cases.

Contraindications and Patient Selection

Absolute Contraindications

Absolute contraindications to gingivectomy encompass medical and local conditions that pose an unacceptably high risk of severe complications, such as life-threatening infection, excessive bleeding, or failure of wound healing, rendering the procedure strictly inadvisable. These prohibitions prioritize patient safety and are based on established periodontal guidelines that emphasize preoperative assessment of systemic health and oral status. Local anatomical factors represent a primary category of absolute contraindications, including the presence of intrabony defects, suprabony pockets with osseous involvement, periodontal pockets extending beyond the mucogingival junction (typically >5-6 mm), and inadequate width of attached or keratinized gingiva (e.g., <2 mm), as these preclude effective soft-tissue resection without bone management. Uncontrolled systemic diseases represent another primary category of absolute contraindications, particularly those impairing immune response, coagulation, or healing. In patients with uncontrolled diabetes mellitus, defined by HbA1c levels exceeding 10%, elective periodontal surgery like gingivectomy is prohibited due to heightened risks of postoperative infection, delayed healing, and flap dehiscence; emergency interventions may be considered only after physician consultation and glycemic stabilization. Similarly, active leukemia, especially acute forms, contraindicates invasive procedures such as gingivectomy when neutrophil counts fall below 1,000 cells/mm³ or platelet counts are under 50,000 cells/mm³, as these thresholds increase susceptibility to hemorrhage and opportunistic infections. Severe immunosuppression from conditions like advanced HIV or high-dose immunosuppressive therapy further prohibits the procedure, as it elevates the infection risk in a manner that cannot be adequately mitigated without resolving the underlying deficit. Acute oral infections also constitute an absolute barrier, including untreated periodontal abscesses or rampant caries adjacent to the surgical site, which could disseminate bacteria systemically during tissue manipulation. These local factors demand resolution through nonsurgical means prior to any consideration of gingivectomy to prevent exacerbation of the infection. Finally, poor patient compliance, manifested as inability to maintain adequate oral hygiene or adhere to postoperative protocols, serves as an absolute contraindication, as it directly leads to treatment failure through recurrent plaque accumulation and impaired healing. This is particularly critical in gingivectomy, where precise plaque control is essential for gingival reattachment and long-term stability.

Relative Contraindications and Precautions

Relative contraindications for gingivectomy include conditions that elevate procedural risks but can often be managed with appropriate precautions, modifications, or consultations, distinguishing them from absolute contraindications that preclude the procedure entirely. Patients with coagulation disorders, such as hemophilia or those on anticoagulant therapy (e.g., warfarin, direct oral anticoagulants like rivaroxaban), require hematologic consultation prior to gingivectomy due to heightened bleeding risks during tissue excision. Therapy interruption may be considered in select cases, such as stopping warfarin 4-5 days preoperatively with physician oversight, though guidelines generally recommend continuing most regimens for periodontal surgery while employing local hemostatic measures like pressure, suturing, or tranexamic acid mouthwashes to control hemorrhage. Pregnancy represents another relative , particularly in the first , where elective procedures like gingivectomy should be deferred to minimize risks of spontaneous during ; the second is preferred for necessary interventions, with limitations on (e.g., avoiding excessive epinephrine) and patient positioning to prevent vena cava . Multidisciplinary coordination with the obstetrician is essential to weigh benefits against potential fetal , ensuring only essential periodontal proceeds. Smoking or poor oral hygiene further complicates gingivectomy outcomes by impairing wound healing and increasing infection susceptibility, often necessitating pre-surgical patient education on cessation or improved plaque control, alongside adjunctive therapies such as chlorhexidine rinses to mitigate delayed epithelialization and gingival recession. Cigarette smoking specifically hinders periodontal regeneration post-surgery, with studies indicating poorer clinical attachment gains and higher complication rates in smokers, underscoring the need for motivational counseling to optimize results.

Surgical Techniques

Conventional Scalpel Gingivectomy

The conventional scalpel gingivectomy is a manual surgical technique that involves the excision of gingival tissue to recontour the gingival margins and eliminate suprabony periodontal pockets. The procedure begins with marking the depths of the periodontal pockets using a periodontal probe or pocket marker to identify bleeding points, typically at depths of 4-5 mm, which guide the extent of tissue removal. An external bevel incision is then made at a 45-degree angle using a No. 15 Bard-Parker blade, starting from the bleeding points and extending slightly beyond to create a crevicular incision that preserves adequate keratinized gingiva. Interdental tissue is released with specialized knives, followed by the removal of tissue tags using curettes and scissors to ensure a smooth contour. Hemostasis is achieved through direct pressure with sterile gauze or, in some cases, intermittent suturing with resorbable materials. Key instrumentation includes the No. 15 Bard-Parker scalpel blade for primary incisions, Kirkland knives for facial and lingual surface cuts due to their broad, flat blades that allow precise tissue separation, and Orban knives for interdental areas owing to their angled, tapered design that facilitates access to confined spaces. Curettes, such as the Gracey or universal types, are employed for debridement of residual tissue and root planing to remove inflammatory exudate and calculus. This method offers advantages such as high precision in incision placement, low cost compared to alternative technologies, and excellent tactile feedback that enables the surgeon to gauge tissue resistance and depth accurately. It also promotes rapid wound healing with minimal lateral thermal damage to adjacent tissues. However, disadvantages include increased intraoperative bleeding requiring manual control, potential postoperative pain and swelling, and the demand for a highly skilled surgeon to achieve optimal outcomes without excessive tissue loss. Post-operative protocols, such as application of a periodontal dressing, support healing as detailed in subsequent sections.

Electrosurgical Gingivectomy

Electrosurgery in gingivectomy utilizes high-frequency radiofrequency currents, typically ranging from 0.5 to 4 MHz, delivered through an active electrode to convert electrical energy into thermal energy via tissue resistance, enabling simultaneous cutting and coagulation of gingival tissue. The process involves ion oscillation that generates intracellular heat, leading to rapid vaporization of cells at temperatures exceeding 100°C for incision and desiccation at 60°C or higher for hemostasis, minimizing blood loss during the procedure. This mechanism differs from mechanical cutting by providing inherent cauterization, which seals vessels as tissue is excised. The technique requires a monopolar electrosurgical unit with an active electrode, such as a needle or wire tip, and a grounding plate for current return, ensuring patient safety and effective energy delivery. The surgeon marks the incision line on the gingival margin, then applies the electrode along this path at a controlled speed of approximately 7 mm per second to avoid excessive heat buildup, using continuous fully rectified waveforms for cutting at higher power settings (e.g., 50-100 W) and pulsed or damped modes at lower power (e.g., 20-50 W) for coagulation. Tissue is kept moist with saline to prevent charring, and the electrode is periodically cooled during pauses—8 seconds for needle tips—to maintain precision; care is taken to avoid contact with bone or restorations to prevent thermal damage. Compared to scalpel methods, electrosurgery offers less precise incisions but integrates hemostasis without additional steps. Advantages of electrosurgical gingivectomy include minimal intraoperative bleeding due to simultaneous coagulation, resulting in a clearer operative field and reduced need for sutures, as well as shorter procedure times and lower postoperative discomfort in many cases. It is also cost-effective relative to laser alternatives and provides self-sterilization of the electrode tip through heat, potentially decreasing infection risk. However, disadvantages encompass risks of thermal injury to adjacent structures, such as underlying bone necrosis or gingival recession if the electrode contacts osseous tissue, along with potential delayed wound healing from excessive heat and an unpleasant odor from tissue vaporization. Contraindications include patients with pacemakers due to electromagnetic interference, and the technique demands operator expertise to mitigate lateral heat spread and tissue charring.

Laser Gingivectomy

Laser gingivectomy utilizes various laser systems for precise soft tissue ablation in periodontal surgery, primarily diode, Nd:YAG, CO2, and Er:YAG lasers, which are effective for vaporizing gingival tissue. Diode lasers operate at wavelengths of 810–940 nm with power settings typically ranging from 0.8–5 W, allowing for efficient soft tissue cutting and coagulation. Nd:YAG lasers operate at a wavelength of 1064 nm with power settings typically ranging from 1–10 W in pulsed mode (e.g., 10–50 Hz), providing deep tissue penetration and excellent hemostasis. CO2 lasers function at 10,600 nm and use power outputs of 5–15 W in pulsed or continuous modes, enabling non-contact vaporization ideal for gingival contouring. Er:YAG lasers, with a wavelength of 2,940 nm and power settings of 2–5.4 W (often 40–80 mJ/pulse at 30 Hz for incisions), provide precise ablation with minimal thermal damage due to high water absorption in tissues. The procedure involves non-contact or contact-mode application along gingival contours to remove excess tissue, often delivered via fiber optic systems such as 200–400 μm fibers for diode lasers or 0.8–1.3 mm tips for Er:YAG lasers, with water spray used in Er:YAG to prevent overheating. Tissue is ablated layer by layer, achieving hemostasis through vessel sealing up to 0.5 mm in diameter, and the bactericidal effects of these lasers—particularly from diode and Er:YAG—reduce bacterial load by decontaminating the site, thereby lowering postoperative infection risk. Local anesthesia may be applied in 30–90% of cases, and sutures are typically unnecessary due to the self-sealing nature of laser incisions. Benefits of laser gingivectomy include significantly reduced postoperative pain (e.g., VAS scores of 2.4/10 versus 7.1/10 for conventional methods), minimal swelling and edema, and decreased bleeding, facilitating faster healing with improved esthetics and no need for analgesics in many instances. These advantages stem from the lasers' ability to provide a sterile field and thin coagulation zones (18–38 μm). However, drawbacks encompass high equipment costs, potential for tissue charring if power settings or water cooling are not properly calibrated, and occasionally longer operative times compared to traditional techniques.

Post-Operative Management and Healing

Immediate Post-Operative Care

Following gingivectomy, pain management typically involves the administration of nonsteroidal anti-inflammatory drugs (NSAIDs) such as ibuprofen at doses of 400-600 mg every 6 hours or acetaminophen at 500 mg every 6 hours for moderate to severe pain, often starting preemptively as anesthesia wears off. Periodontal dressings may be applied to protect the surgical site and promote hemostasis and healing. Cold compresses or ice packs applied externally to the face over the surgical site for 10-20 minutes at a time during the first 24-48 hours help reduce swelling and associated discomfort. Oral hygiene protocols emphasize gentle care to prevent disruption of the surgical site; patients should avoid brushing or flossing the operated area for the first 24-48 hours to allow initial clot stabilization. Starting on postoperative day 1, rinsing with 0.12% chlorhexidine gluconate mouthwash twice daily for 1-2 weeks is recommended to control plaque and promote early wound healing by reducing gingival inflammation. Alternatively, warm saline rinses (1 teaspoon salt in 8 ounces of water) may be used 4-6 times daily after the first day if chlorhexidine is not prescribed. Dietary restrictions focus on minimizing irritation and mechanical trauma; a soft food diet is advised for the first week, including items like yogurt, mashed potatoes, and smoothies, while avoiding hot, spicy, crunchy, or sticky foods that could dislodge the periodontal dressing or exacerbate bleeding. Patients should chew on the opposite side of the mouth and maintain hydration with room-temperature fluids. Additionally, strenuous physical activity should be limited for at least 24 hours to reduce the risk of increased bleeding, with head elevation during rest to further aid in hemostasis. Technique-specific bleeding control measures, such as pressure with gauze, may be applied immediately post-procedure as needed.

Healing Process and Long-Term Outcomes

The healing process following gingivectomy occurs primarily by secondary intention, involving a series of biological phases that restore gingival tissue integrity. The initial hemostasis phase (0-24 hours) features blood vessel contraction and clot formation to control bleeding and provide a provisional matrix for tissue repair. This is followed by the inflammation phase (1-3 days), during which inflammatory cells such as polymorphonuclear leukocytes and macrophages infiltrate the site to clear debris and pathogens, accompanied by signs of erythema and edema. Epithelial cell migration begins toward the end of this phase, initiating coverage of the wound surface. In the proliferation phase (3-21 days), granulation tissue forms through angiogenesis and fibroblast activity, supporting reepithelialization as new epithelial cells migrate from the wound margins to cover the defect, typically completing surface epithelialization by 5-14 days. Collagen deposition strengthens the tissue during this period. The remodeling phase (weeks to months) involves collagen reorganization from type III to type I, reducing cellularity and enhancing tensile strength, with full maturation of the gingival sulcus often achieved by 4-5 weeks for epithelium and up to 7 weeks for connective tissue. Throughout these stages, the dentogingival junction reforms, resembling presurgical contours by 35 days in uncomplicated cases. Several factors influence the healing trajectory, including patient age, where older individuals may experience delayed epithelialization due to reduced cellular proliferation; nutritional status, as deficiencies in vitamins like C impair collagen synthesis; and smoking, which compromises vascularization and increases inflammation. Optimal oral hygiene and absence of systemic conditions like diabetes further promote efficient repair. Long-term outcomes typically include average pocket depth reduction of 2-3 mm, reflecting elimination of suprabony pockets and establishment of stable gingival attachment levels. The gingival margin stabilizes by 3-6 months, with minimal rebound in healthy tissues, leading to improved periodontal health and aesthetics. Monitoring involves follow-up visits at 1 week to assess initial epithelial coverage and inflammation, 1 month for granulation tissue evaluation, and 3 months to confirm remodeling and pocket stability through clinical probing and indices like bleeding on probing. High success rates are achieved in uncomplicated cases, defined by sustained pocket reduction and absence of reinflammation, as reported in periodontal studies emphasizing maintenance care.

Complications and Risks

Common Complications

Postoperative bleeding is a frequent complication following gingivectomy due to the highly vascular nature of the gingival tissue, with mild to moderate bleeding reported in approximately 3.5% of cases across periodontal surgeries including gingivectomy. This can manifest as oozing from the surgical site, typically controlled intraoperatively but potentially persisting postoperatively if hemostasis is incomplete. In more invasive variants, such as those involving deeper tissue resection, the incidence may approach higher rates, though excessive bleeding remains uncommon at around 1-3% without underlying coagulopathies. Infection occurs in about 1-5% of gingivectomy procedures, presenting with signs such as increased swelling, erythema, or pus formation, often linked to poor oral hygiene or contamination during healing. Delayed wound healing may exacerbate this risk, particularly in patients with suboptimal plaque control, leading to prolonged inflammation and potential abscess formation. Studies indicate that the overall postoperative infection rate for gingivectomy is low, at roughly 2.2%, but can rise with factors like smoking or systemic conditions. Gingival recession is another common adverse event, resulting from excessive tissue removal or uneven resection, which exposes root surfaces and causes dentin hypersensitivity in affected areas. This sensitivity, reported in up to 5.7% of postoperative cases, arises as the protective cementum is denuded, leading to discomfort from thermal, tactile, or osmotic stimuli. Aesthetic concerns, including uneven gingival contours or scarring, are particularly noted in procedures using laser or electrosurgery, where thermal effects can cause tissue charring or fibrosis, affecting smile esthetics in visible anterior regions. Such issues occur more frequently with these modalities due to collateral heat damage, though overall complication rates for gingivectomy remain low at 5-7%.

Prevention and Management Strategies

Prevention of complications following gingivectomy begins with targeted preoperative measures for patients at elevated risk of infection, such as those with cardiac conditions predisposing to infective endocarditis. In these cases, antibiotic prophylaxis with a single dose of amoxicillin (2 g orally) administered 30 to 60 minutes prior to the procedure is recommended to mitigate the risk of bacteremia-induced complications. During surgery, meticulous hemostasis is essential to minimize postoperative bleeding, achieved through techniques such as pressure application, suturing, or the use of topical agents to ensure a clear operative field and promote stable clot formation. Additionally, comprehensive patient education on postoperative oral hygiene practices, including gentle brushing with soft-bristled toothbrushes and the use of prescribed antimicrobial rinses, plays a critical role in preventing infection and supporting tissue healing. If complications arise, management strategies are tailored to the specific issue. Persistent bleeding is typically addressed with local hemostatic agents, such as oxidized cellulose sponges, which promote clot formation and are applied directly to the site for effective control without systemic intervention. Infections, should they develop, are managed with systemic antibiotics; amoxicillin at 500 mg three times daily for 7 days is a standard regimen for dental surgical site infections due to its broad-spectrum coverage against common oral pathogens. For gingival recession resulting from excessive tissue removal, surgical revision through procedures like connective tissue grafts or coronally advanced flaps can restore coverage and aesthetics, with high success rates in suitable cases. Early intervention in potential complications significantly enhances prognosis, allowing for prompt resolution and reduced need for further procedures. In monitored clinical settings, reoperation rates following gingivectomy remain low, with overall complication incidences around 5%, underscoring the efficacy of proactive strategies.