Pulpitis
Pulpitis is an inflammatory condition of the dental pulp, the soft connective tissue within the tooth that contains nerves, blood vessels, and other vital structures, primarily triggered by bacterial invasion secondary to untreated dental caries or mechanical trauma such as cracks or restorative procedures.[1] This inflammation arises from microbial infection that increases intrapulpal pressure and releases inflammatory mediators, leading to pain and potential progression to pulp necrosis if untreated.[1] Pulpitis is classified into two main types: reversible, where the inflammation is mild and the pulp can potentially heal with removal of the irritant, and irreversible, characterized by severe, non-resolving inflammation that necessitates pulp removal to prevent further complications like apical periodontitis.[2] Reversible pulpitis typically presents with sharp, transient pain elicited by stimuli such as cold, heat, or sweets, lasting less than 10-30 seconds and subsiding quickly upon removal of the stimulus, often without spontaneous discomfort or radiographic changes.[3] In contrast, irreversible pulpitis involves more intense symptoms, including prolonged lingering pain after stimuli, spontaneous throbbing or aching that may worsen at night or with posture changes, and possible referral to adjacent areas, reflecting deeper tissue damage with histological features like hyperemia, acute inflammation, and focal necrosis.[2][3] Diagnosis relies on clinical evaluation, including patient history, thermal and electric pulp testing, and percussion sensitivity, though histological confirmation post-extraction reveals discrepancies between clinical and actual tissue status.[3] Treatment for reversible pulpitis focuses on conservative vital pulp therapy, such as indirect pulp capping or removal of caries to allow healing and preserve tooth vitality, achieving success rates over 80% in deep caries cases.[4] For irreversible pulpitis, the standard approach is root canal therapy involving pulpectomy to eliminate infected tissue, followed by obturation, though emerging minimally invasive techniques like antibiotic-steroid mixtures and ultrasound-guided interventions aim to salvage pulp in select cases.[1] Early intervention is critical, as untreated pulpitis can lead to abscess formation or tooth loss, underscoring the importance of prompt dental care.[2]Fundamentals
Definition and Anatomy
Pulpitis is defined as the inflammation of the dental pulp, a soft connective tissue housed within the pulp chamber of the crown and the root canals of the tooth, comprising nerves, blood vessels, lymphatic components, and cellular elements essential for tooth vitality.[5] This condition arises from perturbations to the pulp's integrity, potentially leading to pain and tissue damage if unresolved.[6] The dental pulp exhibits a structured organization, divided into coronal and radicular portions. The coronal pulp occupies the pulp chamber in the tooth crown, featuring expansive dimensions and pulp horns that extend toward the incisal or occlusal surfaces and cusps, facilitating proximity to dentin-forming processes. In contrast, the radicular pulp resides within the root canals, narrowing progressively from the cervical region to the apical foramen, where it connects to the periodontal ligament.[5] Key cellular components include odontoblasts, which form a peripheral layer of columnar cells responsible for dentinogenesis through processes extending into dentinal tubules; fibroblasts, which synthesize and maintain the extracellular matrix; and leukocytes, including immune cells such as macrophages, histiocytes, mast cells, plasma cells, and lymphocytes, which comprise approximately 1% of the total cells in healthy dental pulp.[5][6] The vascular supply to the dental pulp derives primarily from branches of the inferior alveolar artery for mandibular teeth and the posterior superior alveolar artery for maxillary teeth, entering via the apical foramen to form a capillary network, including a prominent subodontoblastic plexus that supports odontoblast nutrition.[5] Innervation is provided by sensory branches of the trigeminal nerve (cranial nerve V), with afferent fibers forming the plexus of Raschkow—a nerve network subjacent to the odontoblasts—transmitting nociceptive signals; these include 10-30% myelinated Aδ fibers for sharp pain and 70-90% unmyelinated C fibers for dull, throbbing sensations. Sympathetic fibers from the superior cervical ganglion modulate pulpal blood flow via vasoconstriction.[5][6] The dental pulp was first formally described in 1543 by anatomist Andreas Vesalius in his seminal atlas De Humani Corporis Fabrica, depicting it as a central sinus within the tooth. Pulpitis, as an inflammatory response, gained recognition in early 19th-century dental literature amid advancing understandings of tooth pathology, with modern histological insights emerging from post-1950s studies, notably Harold R. Stanley's 1976 work on pulpal histology in health, disease, and repair.[7][6] Pulpitis is broadly classified into reversible and irreversible forms depending on the extent of inflammation and potential for resolution.[5]Classification
Pulpitis is primarily classified into reversible and irreversible forms based on the severity of inflammation and the pulp's capacity for recovery. Reversible pulpitis represents a mild inflammatory condition where the pulp tissue can return to a normal state following the removal of the causative irritant, such as shallow caries or minor trauma.[8] In contrast, irreversible pulpitis involves more severe, progressive inflammation that the pulp cannot heal from, often leading to partial or total necrosis if untreated.[9] This classification guides clinical management by distinguishing treatable cases from those requiring more invasive interventions.[2] Subtypes further refine this categorization. Reversible pulpitis may present as acute, characterized by sharp, transient pain in response to stimuli like cold or sweets, or chronic, involving mild, intermittent discomfort often associated with pulp fibrosis.[2] Hyperemic pulpitis, an early stage of reversible inflammation, features localized congestion and edema due to increased blood flow in response to irritants. Irreversible pulpitis is subdivided into symptomatic and asymptomatic forms; the symptomatic variant includes acute cases with sudden, intense, lingering pain (often exceeding 30 seconds after stimulus removal) and spontaneous episodes, while chronic cases exhibit persistent low-grade throbbing.[8] Asymptomatic irreversible pulpitis lacks overt pain but shows subclinical inflammation, typically from deep caries or pulp exposure.[8] Differentiation between reversible and irreversible pulpitis relies on clinical and histological criteria. Clinically, reversible cases show short-duration pain (seconds) that resolves quickly upon stimulus removal, whereas irreversible pulpitis features prolonged pain, hypersensitivity to thermal changes, and potential spontaneity.[8] Histologically, reversible pulpitis displays localized edema, mild inflammation, and increased fibrosis (observed in 63.3% of cases), with minimal necrosis (3.3%).[3] In irreversible pulpitis, widespread acute inflammation (20.8%), severe hyperemia (47.9%), and focal necrosis (14.6%) predominate, correlating significantly with clinical diagnoses (P < 0.005 for hyperemia and fibrosis).[3] These features reflect the pulp's progression from recoverable congestion to irreversible tissue breakdown.[3]Epidemiology and Etiology
Prevalence and Risk Factors
Pulpitis is a common condition within endodontic practice, with irreversible pulpitis accounting for approximately 30-50% of cases presenting for root canal treatment globally. In a Brazilian epidemiological study of 1,765 patients, symptomatic irreversible pulpitis was the most prevalent pulp disease, comprising 46.3% of all diagnosed pulp conditions and 26.4% of overall endodontic diseases.[10] Similarly, a retrospective analysis of endodontic referrals reported irreversible pulpitis in 36% of cases, highlighting its prominence in clinical settings.[11] Orofacial pain, frequently attributable to pulpitis and linked to untreated caries progression, has a prevalence ranging from 5% to 57% in adults over the last 12 months, varying by country and socioeconomic factors.[12] Recent data from tertiary care centers indicate a prevalence of around 34.6% for pulpitis among patients seeking emergency dental care.[13] Demographic factors significantly influence the occurrence of pulpitis, with higher rates observed among females, who comprise a majority of endodontic patients (e.g., 65% in one study).[11] Incidence is common in adults aged 20-50 years, coinciding with higher exposure to cariogenic diets and occupational stressors that may exacerbate oral health neglect. Socioeconomic disparities play a critical role, as individuals in low-income groups and regions with limited dental access exhibit elevated rates due to delayed treatment of precursor conditions like caries. In developing countries, where oral health infrastructure is underdeveloped, pulpitis prevalence can exceed 40% in underserved populations.[14] Key risk factors for pulpitis include poor oral hygiene, which facilitates bacterial ingress and inflammation, and systemic conditions such as diabetes, which impairs pulpal healing and increases susceptibility through altered immune responses.[15] Smoking is another major contributor, reducing pulpal vascularity and antimicrobial defenses, with smokers showing increased risk of endodontic pathology.[16] Genetic predispositions, such as enamel defects, further heighten vulnerability by accelerating caries penetration to the pulp, as evidenced in cohort studies of familial dental anomalies and recent genome-wide association studies indicating pulpal infections affect over 80% of adults.[17][18] These factors disproportionately affect high-risk groups, underscoring the need for targeted prevention in vulnerable demographics. Recent global estimates as of 2023 suggest pulpal and periapical diseases remain highly prevalent, with irreversible pulpitis comprising 30-40% of endodontic presentations.[13]Causes
The primary cause of pulpitis is bacterial invasion of the dental pulp, most commonly originating from advanced dental caries in which acid-producing bacteria erode the enamel and dentin, eventually exposing the pulp to microbial penetration.[9] Streptococcus mutans is a key etiological agent in this process, as it adheres to tooth surfaces, metabolizes carbohydrates into acids, and facilitates biofilm formation that propagates carious lesions toward the pulp.[19] This invasion often culminates in direct pulp exposure when the carious defect breaches the dentin-pulp interface.[20] Secondary causes encompass a range of non-carious triggers that compromise pulpal integrity or permit bacterial entry. Traumatic injuries, including crown and root fractures as well as luxations, can directly expose the pulp or sever vascular supply, particularly in anterior teeth affected by impacts or sports-related accidents.[21] Iatrogenic factors during dental treatment, such as overly deep restorations encroaching on the pulp, mechanical pulp exposure during excavation, or excessive pressure from orthodontic forces, also initiate inflammation.[22] Chemical and thermal irritants further contribute as secondary etiologies. Chemical agents, including phosphoric acid etchants, acrylic monomers in provisional restorations, or eugenol-free medicaments, provoke pulpal responses upon direct contact or diffusion through dentin.[22] Thermal extremes, such as heat generated from high-speed rotary instrumentation without sufficient water coolant or from exothermic setting of restorative materials, induce protein denaturation and inflammatory cascades in the pulp.[21] Additional factors include the extension of infection from adjacent periodontal disease via lateral canals or furcation areas, as well as ingress through dentinal cracks or vertical fractures that provide pathways for bacteria.[21] Rarely, systemic conditions such as autoimmune disorders like rheumatoid arthritis can influence pulpal vulnerability by promoting heightened inflammatory responses in oral tissues, though these are not direct initiators.[23] Poor oral hygiene and dietary habits serve as predisposing risk factors that amplify the incidence of these causal events.[20]Pathophysiology
Inflammatory Response
The inflammatory response in pulpitis begins with activation of the innate immune system, primarily triggered by bacterial invasion or other irritants entering the dental pulp through dentinal tubules. This initial phase involves rapid recruitment of neutrophils and macrophages to the site of injury, where they phagocytose pathogens and release pro-inflammatory mediators. Neutrophils predominate in the acute stage, forming the first line of defense, while macrophages follow to clear debris and amplify the response.[6] Key cytokines such as interleukin-1 (IL-1α and IL-1β) and tumor necrosis factor-alpha (TNF-α), secreted by these innate immune cells and activated odontoblasts, orchestrate the inflammatory cascade. These cytokines induce vasodilation of pulp microvasculature, increasing blood flow and permeability, which leads to plasma extravasation and localized edema within the confined pulp space. This edema contributes to elevated intrapulpal pressure, exacerbating tissue stress. Additionally, IL-1 and TNF-α promote further immune cell recruitment by upregulating adhesion molecules on endothelial cells.[24][25] In chronic or prolonged pulpitis, the adaptive immune response engages, involving T-cells and B-cells that infiltrate the pulp tissue. T-cells, particularly CD4+ helper T-cells, coordinate the response by secreting additional cytokines, while B-cells differentiate into plasma cells that produce antibodies targeted against persistent antigens. This adaptive phase often follows unresolved innate inflammation and can lead to sustained immune activation.[26][27] Odontoblasts play a dual role in this response, not only sensing danger signals but also contributing to repair by secreting dentin matrix components, including predentin, in an attempt to form reactionary dentin as a protective barrier. This secretion is upregulated in response to mild inflammatory stimuli, allowing surviving odontoblasts to deposit mineralizable matrix that reinforces the dentin-pulp complex. However, in severe cases, odontoblast disruption limits this reparative function.[25][28] The progression of inflammation typically starts with hyperemia, characterized histologically by dilated and congested blood vessels with minimal cellular infiltrate. As the response intensifies, it advances to suppurative stages with neutrophil-dominated abscess formation, where focal collections of pus, leukocytes, and bacteria accumulate. In irreversible pulpitis, widespread abscesses coalesce, leading to liquefaction necrosis, a proteolytic breakdown of pulp tissue into a softened, necrotic mass due to enzymatic digestion by inflammatory cells and bacterial products. This necrotic progression ultimately compromises pulp vitality if untreated.[29][30][31]Neurological Response
The dental pulp is richly innervated by sensory neurons originating from the trigeminal ganglion, which enter the tooth via the apical foramen and form the pulp-dentin complex's nerve plexus. These include myelinated A-delta fibers, responsible for transmitting sharp, localized pain in response to hydrodynamic stimuli such as cold or mechanical irritation, and unmyelinated C-fibers, which convey dull, aching, diffuse pain from deeper inflammatory processes.[32][33][34] In pulpitis, inflammation sensitizes these nociceptors through mediators like prostaglandins and bradykinin, which lower the activation threshold of nerve endings by depolarizing membranes and enhancing excitatory neurotransmitter release. This peripheral sensitization leads to hyperalgesia, where even mild stimuli provoke exaggerated pain responses, while central sensitization in the trigeminal pathways amplifies signal processing in the brainstem and thalamus, contributing to prolonged discomfort. Consequently, severe cases often involve referred pain, where C-fiber activation causes poorly localized sensations in adjacent orofacial regions due to convergence of trigeminal inputs.[32][33][35] The neurological response differs markedly between reversible and irreversible pulpitis. In reversible pulpitis, pain is typically brief and stimulus-evoked, primarily mediated by A-delta fibers, subsiding quickly upon removal of the trigger as inflammation remains mild. In contrast, irreversible pulpitis features spontaneous, throbbing pain that worsens at night, driven by persistent C-fiber activation and heightened sensitization from accumulated inflammatory mediators like bradykinin, often resulting in lingering hyperalgesia even after stimuli cessation.[32][33][34]Clinical Presentation
Signs
Pulpitis manifests through several observable physical signs that clinicians detect during examination, primarily involving the affected tooth and surrounding tissues. Tooth tenderness to percussion or palpation is a common sign, particularly in cases where inflammation has extended beyond the pulp to involve periapical structures, resulting from pressure on inflamed tissues.[36] In advanced stages, swelling may appear as a periapical abscess, presenting as localized soft tissue expansion around the tooth apex due to accumulated inflammatory exudate.[37] Additionally, tooth discoloration, often a grayish hue, can occur when pulp necrosis follows prolonged inflammation, altering the internal appearance visible through the enamel.[37] Tooth mobility may also be observed in severe inflammation with significant periapical involvement, indicating bone resorption from extended infection.[38] Reversible pulpitis typically shows minimal external physical signs, with the tooth appearing clinically normal aside from possible mild sensitivity during testing, as the inflammation is confined to the pulp without periapical extension.[39] In contrast, irreversible pulpitis may progress to exhibit more pronounced signs if it leads to partial necrosis or periapical involvement, such as gingival swelling or the presence of a sinus tract draining from the apex, reflecting bacterial spread beyond the pulp.[40] These differences aid in distinguishing the stages, with reversible cases lacking overt tissue changes while advanced irreversible cases demonstrate escalating involvement of adjacent structures. These signs hold diagnostic relevance, particularly those indicating periapical extension like tenderness to percussion or swelling, which signal the need for advanced intervention as outlined in the 2023 European Society of Endodontology guidelines.[36] Such indicators, stemming briefly from edema-induced pressure in the inflammatory response, guide clinicians toward root canal therapy to prevent further complications.[37]Symptoms
Pulpitis manifests primarily through patient-reported pain experiences, which vary in intensity, duration, and triggers depending on whether the condition is reversible or irreversible. These symptoms reflect the inflammatory process within the dental pulp and serve as key elements in clinical history-taking. In endodontic practices, pulpitis accounts for approximately 27% of emergency patient visits, highlighting its common presentation as a cause of dental pain.[41] In reversible pulpitis, patients typically report sharp, transient pain elicited by specific stimuli such as cold temperatures, sweet substances, or occasionally hot items. This discomfort is brief, lasting only 1-2 seconds after the stimulus is removed, and resolves completely without lingering effects. There is no spontaneous pain, and the sensation is well-localized to the affected tooth. These symptoms arise from mild pulp inflammation that can subside with removal of the irritant, often linked to early caries or restorative procedures. Irreversible pulpitis, in contrast, involves more severe and persistent pain that indicates advanced inflammation unlikely to resolve without intervention. Patients describe a throbbing, aching, or dull nagging pain that may occur spontaneously, without any obvious trigger, and often intensifies at night or when lying down due to increased blood flow to the head. Pain triggered by thermal stimuli, particularly heat, lingers for minutes or more after the stimulus is removed, and may also respond to cold or sweets with prolonged duration exceeding 20-30 seconds; in some cases, cold may provide temporary relief. The discomfort can radiate to adjacent areas such as the jaw, ear, or other teeth, making precise localization challenging. These pain patterns stem from heightened neurological responses in the inflamed pulp tissue. Associated symptoms in pulpitis include heightened sensitivity to biting pressure on the affected tooth, which patients perceive as discomfort during chewing, particularly in irreversible cases. In acute presentations with systemic involvement, some individuals report a mild fever accompanying the pain, signaling a broader inflammatory response.Diagnosis
Clinical Assessment
The clinical assessment of pulpitis begins with a thorough patient history to identify key indicators of pulpal inflammation. Clinicians elicit details on the onset and duration of pain, which may be sudden following trauma or gradual with advancing caries, and assess aggravating or relieving factors such as thermal stimuli, sweets, or pressure from biting.[37] Spontaneous pain that persists beyond stimulus removal suggests progression to irreversible pulpitis, while pain that resolves quickly points to reversible forms.[42] Relevant medical history, including recent dental trauma or systemic conditions like diabetes that may impair healing, is also documented to contextualize the presentation.[37] Physical examination follows, starting with visual inspection of the affected tooth and surrounding structures to detect caries, fractures, cracks, defective restorations, or soft tissue swelling indicative of extension beyond the pulp.[42] Palpation of the buccal and lingual gingiva and apical regions evaluates for tenderness or fluctuance, which may signal periapical involvement.[37] Percussion testing, involving gentle tapping on the occlusal surface or crown with a dental instrument, assesses for elicited pain, a common finding in inflamed or necrotic pulps that helps localize the source.[42] These non-invasive steps, often aided by good lighting and magnification, allow initial suspicion of pulpitis while noting associated signs like tooth mobility or periodontal probing depths.[37] Differential diagnosis is essential to distinguish pulpitis from mimicking conditions, guided by the 2023 European Society of Endodontology (ESE) S3-level clinical practice guidelines.[42] Vertical root cracks or fractured teeth may present with similar sharp, localized pain on biting but lack thermal sensitivity and show radiographic lines or explorer-detectable fissures.[37] Maxillary sinusitis can cause referred pain to posterior teeth, often with nasal congestion or unilateral facial pressure, requiring otorhinolaryngologic evaluation if extraoral signs predominate.[43] Temporomandibular disorders (TMD) typically involve broader myofascial pain, joint clicking, or limited jaw movement without dental provocation, necessitating targeted TMD screening.[44] Integration of history and exam findings, corroborated by radiographs, ensures accurate differentiation per ESE recommendations.[42]Vitality Testing
Vitality testing is a critical component in diagnosing pulpitis, distinguishing between reversible and irreversible forms by evaluating the pulp's sensory response or blood flow to confirm vitality and guide treatment decisions. These tests primarily assess pulp sensibility through neural stimulation or directly measure vascular supply, providing objective data beyond subjective symptoms. Traditional methods focus on thermal and electrical stimuli, while emerging techniques like laser Doppler flowmetry offer more physiological insights into true vitality.[45] Thermal tests apply controlled temperature changes to the tooth surface to elicit a pulpal response via hydrodynamic theory, where stimulus-induced fluid movement in dentinal tubules stimulates nerve endings. Cold testing, often using ethyl chloride spray (-12.3°C) applied via a cotton pellet to the middle third of the crown for 5 seconds, produces a sharp, brief pain in vital pulps; a mild, short-lived response suggests reversible pulpitis, whereas lingering pain beyond 10 seconds indicates irreversible pulpitis.[46] Heat testing employs heated gutta-percha (120-140°C) applied briefly to the lubricated tooth surface, with similar interpretive criteria: quick resolution points to reversible inflammation, but prolonged aching signals irreversible damage; heat tests are less commonly used due to lower accuracy compared to cold methods, achieving near 100% reliability only with precise application to avoid false positives in restored teeth.[45][46] Electric pulp testing (EPT) delivers a gradually increasing electrical current (typically starting at 0 μA) via a probe placed on the labial or occlusal surface to stimulate Aδ nerve fibers, recording the threshold at which the patient reports a tingling sensation. In vital pulps, normal thresholds range from 2 to 20 μA, with higher values (e.g., >40 μA) potentially indicating partial inflammation or conduction issues; no response suggests necrosis, while an exaggerated low-threshold reaction may denote reversible pulpitis, and prolonged pain post-stimulation aligns with irreversible cases.[47] EPT achieves 90-100% accuracy in mature teeth but is less reliable in multi-rooted molars, where false negatives can occur if only one canal is vital, as the current may not uniformly stimulate all root canals.[45][47] The test cavity method serves as a definitive but invasive option when noninvasive tests are inconclusive, involving the preparation of a small, anesthetic-free cavity into the dentin to directly provoke pulpal pain through mechanical exposure. A positive pain response confirms vitality, distinguishing reversible from irreversible pulpitis based on pain intensity and duration, though this technique is rarely employed due to its irreversibility and patient discomfort.[45] Laser Doppler flowmetry (LDF) represents an emerging, noninvasive vitality assessment by directing a low-power laser (e.g., 633 nm wavelength) at the tooth crown to measure pulpal blood flow via Doppler shift in reflected light from moving red blood cells, outputting results in perfusion units (PU). Recent studies establish normal PBF ranges of 6-14 PU in permanent incisors, with reduced flux (<40% of contralateral control) indicating compromised vitality in pulpitis cases; LDF outperforms sensibility tests by directly evaluating vascular status, showing 90% coincidence with clinical vitality in traumatized teeth and high specificity (99.88%), though it remains technique-sensitive due to gingival signal interference.[48][49] Overall, a positive response across these tests affirms pulp vitality, but clinicians must consider false negatives in multi-rooted teeth, where heterogeneous pulp status can mask partial necrosis, necessitating adjunctive evaluation.[50]Treatment
Reversible Pulpitis
Reversible pulpitis represents an early inflammatory stage of the dental pulp that can resolve with appropriate conservative intervention, provided the condition is confirmed through clinical assessment and vitality testing indicating pulp responsiveness without prolonged symptoms.[51] The primary treatment involves complete removal of the irritant, typically through selective caries excavation to eliminate bacterial sources while preserving as much healthy tooth structure as possible.[51] In cases of deep caries approaching the pulp but without direct exposure, an indirect pulp capping procedure is applied, where a biocompatible material such as calcium hydroxide or mineral trioxide aggregate (MTA) is placed over the thin remaining dentin to promote reparative dentin formation and protect the pulp.[4] Calcium hydroxide has been traditionally used for its antibacterial properties and ability to stimulate dentin bridging, though MTA is increasingly preferred due to its superior sealing and biocompatibility.[51] Following pulp capping, the tooth is restored with a well-sealed permanent filling, such as composite resin or amalgam, to prevent microleakage and reinfection.[51] For pain management during and after treatment, nonsteroidal anti-inflammatory drugs (NSAIDs) like ibuprofen are recommended as first-line analgesics to control discomfort associated with the inflammation. When treated early, vital pulp therapy for reversible pulpitis achieves healing success rates of 83-95%, with outcomes influenced by factors such as the extent of caries removal and material choice.[4] Clinical and radiographic follow-up is essential, typically at 6-12 months post-treatment, to monitor pulp vitality, absence of symptoms, and absence of periapical pathology.[51]Irreversible Pulpitis
Irreversible pulpitis requires definitive interventions to eliminate the inflamed pulp and prevent progression to periapical pathology, with root canal therapy (RCT) serving as the traditional standard treatment. RCT involves pulpectomy, the complete removal of the inflamed pulp tissue from the root canals, followed by biomechanical cleaning and shaping to remove debris and bacteria, and obturation with a biocompatible material such as gutta-percha to seal the canal system.[52] If the tooth is unrestorable due to extensive structural damage, extraction is indicated to alleviate pain and prevent complications.[53] Vital pulp therapy (VPT) offers a less invasive alternative in select cases, particularly partial pulpotomy, where only the coronal portion of the inflamed pulp is excised, and the remaining vital pulp is capped with biocompatible materials like mineral trioxide aggregate (MTA) or Biodentine to promote healing and dentin bridge formation. Studies from 2023 to 2025 report success rates for VPT in irreversible pulpitis ranging from 76% to 98%, with MTA achieving up to 92% and Biodentine around 87%, depending on follow-up duration and case selection.[54][55] Emerging regenerative endodontic approaches aim to preserve and regenerate pulp vitality using advanced biomaterials, including stem cell scaffolds derived from dental pulp stem cells and platelet-rich fibrin (PRF) to facilitate tissue regeneration in mature teeth. For instance, autologous dental pulp stem cells combined with leukocyte-PRF have shown promise in revitalizing the pulp-dentin complex.[56] Pulp transplantation, involving the transfer of healthy donor pulp tissue, represents a novel experimental strategy to restore function, though clinical application remains limited.[57] A 2024-2025 expert consensus supports pulpotomy, including full pulpotomy with calcium silicate-based cements, as a viable alternative to RCT for mature molars with irreversible pulpitis, emphasizing its high success in preserving tooth vitality when inflammation is confined to the coronal pulp.[58] Following treatment, whether RCT or VPT, the tooth typically requires a crown restoration to reinforce structural integrity and prevent fracture, as the procedure weakens the tooth. Antibiotics are not routinely prescribed for irreversible pulpitis but may be indicated if signs of systemic infection or abscess formation occur post-treatment.[9][37]Prevention and Prognosis
Preventive Strategies
Preventing pulpitis primarily involves strategies to halt the progression of dental caries and minimize trauma to the teeth, as these are the leading causes of pulp inflammation. Effective preventive measures target plaque accumulation, enamel demineralization, and physical injury through a combination of daily personal care and professional interventions. Oral Hygiene PracticesMaintaining rigorous oral hygiene is foundational to preventing pulpitis by reducing bacterial load and promoting enamel remineralization. Brushing teeth twice daily with fluoride toothpaste containing at least 1,000 ppm fluoride significantly lowers the risk of caries development, which can otherwise advance to pulp involvement. Daily flossing removes interdental plaque that brushing misses, further decreasing caries incidence by up to 40% when combined with brushing. Incorporating antimicrobial mouth rinses, such as those with chlorhexidine, can supplement these efforts by inhibiting bacterial growth, particularly in high-risk individuals. Professional Dental Care
Regular professional evaluations and interventions are essential for early detection and management of caries to avert pulpitis. The American Dental Association recommends dental check-ups every six months for most individuals to assess caries risk and perform cleanings, enabling timely intervention before lesions deepen. For caries-prone teeth, particularly molars, the application of pit-and-fissure sealants provides a protective barrier against occlusal decay, reducing caries risk by up to 80% in children and adolescents. Prompt restoration of carious defects or defective fillings prevents bacterial penetration into the pulp, as emphasized in guidelines for managing early carious lesions. Lifestyle Modifications
Dietary and behavioral adjustments play a critical role in mitigating pulpitis risk by addressing cariogenic factors and trauma. Limiting consumption of sugary and acidic foods and beverages reduces acid production by oral bacteria, thereby slowing enamel erosion and caries progression. For individuals engaged in contact sports or activities with fall risks, using custom-fitted mouthguards is advised to protect teeth from fractures that could expose the pulp, with evidence showing a substantial reduction in traumatic dental injuries. The 2025 guidelines from the Scottish Dental Clinical Effectiveness Programme underscore the importance of early caries intervention, such as non-invasive remineralization therapies, to preserve pulp vitality in primary teeth.