The complete and three-dimensional fluid tight seal of the root canal system is the final component of the endodontic triad. The long-standing and closest material which has fulfilled this criterion is gutta-percha (GP). Several materials have been tried and tested as an endodontic filling material, of which GP has been most extensively used for years and has established itself as a gold standard. In addition, it has proved itself successful with different techniques of obturation while maintaining its basic requisites. This article deals briefly with the history and evolution of GP, source, chemical composition, manufacturing, disinfection, cross-reactivity, and advancements in the material. Show
Keywords: Endodontics, gutta-percha, material science INTRODUCTIONThere is always on-going research for newer endodontic obturating materials to obtain better materials than the existing ones to fulfil the biological requisites along with predictable long-term treatment outcome. Several materials have been tried and tested for filling the root canal. The results were variable, from satisfactory to disastrous, at times. Of all the tested materials, gutta-percha (GP) has stood the test of time for years with consistent clinical performance under various clinical situations across the world. As of now, no other materials can be considered as a possible replacement for GP in its various forms. Hence, GP can be considered as a gold standard material for obturation. HISTORYHistory shows that GP has been used for a variety of purposes since the 17th century. Around 1656 an English natural historian John Tradescant introduced GP to Europe and called it “mazer wood.” In 1843, Dr. William Montgomerie further introduced GP to the West. His work was referred to the Medical Board of Calcutta and was awarded a gold medal by The Royal Society of Arts in London. The first patent for GP was obtained in 1864 by Alexander, Cabriot, and Duclos, which opened a Broadway for its industrial use. In 1845, Hancock and Bewley formed the GP Company in United Kingdom. People became infatuated with this new material and it became the first successful insulation for an underwater cable. Its use multiplied rapidly for manufacture of corks, pipes cements, thread, surgical instruments, garments, musical instruments, suspenders, window shades, carpets, gloves, mattresses, pillows, tents, umbrellas, golf balls (gutties), sheathing for ships, and boats were made wholly of GP.[] EVOLUTION OF GUTTA-PERCHA IN DENTISTRY
Some of commercially available GP points brand from earlier period (1970s) were manufactured by companies such as Dent-O-Lux, Indian Head, Mynol, Premier, and Tempryte. More recently, brands such as Tanari (Tanariman, Brazil), Meta (GN Injecta, Brazil), Dentsply (York, USA), Roeko (Coltene, Switzerland), Diadent (Korea), and Sybronendo (Orange, California) are popular since the evolution of NiTi rotary endodontic systems. Apart from GP the alternate materials which have been tried are plastics (Resilon), solids or metal cores (Silver points, Coated cones, Gold, Stainless Steel, Titanium and Irridio-Platinum), and cements and pastes (Calcium Phosphate, Gutta Flow, Hydron, MTA). However, many of these materials do not meet the complete requirements for obturation of root canal systems. Only calcium silicate-based materials like MTA and related bioactive cements have shown promising results. SOURCEGP is a dry coagulated sap of a peculiar species of tropical plants. It was first obtained from Sapotaceae family of trees, which are abundant in the Malay Peninsula (South East Asia). In Malay-getah perca means “percha sap” (plant's name). The trees are mainly found in Malay Archipelago, Singapore, Indonesia, Sumatra, Philippines, Brazil, South America, and other tropical countries. These trees are medium to tall (approximately 30 m) in height, and up to 1 m in trunk diameter. It is usually imported from Central South America for its use in dentistry, which is one of the reasons for its high cost.[] There are many species of Palaquium genus that yield GP of which four are found in India:
COMPOSITIONGP is a trans-isomer of polyisoprene. Its chemical structure is 1, 4, trans–polyisoprene. The molecular structure of GP is close to that of natural rubber from Hevea brasiliensis, which is a cis-isomer of polyisoprene. Both are high-molecular-weight polymers and structured from the same basic building unit or isoprenemer [Table 1].[] Table 1Chemistry Natural rubberGutta percha“Cis” polyisoprene“Trans” polyisopreneCH2 groups on the same side of the double bond to form the polymer of natural rubberCH2 (Methylene group), groups on opposite sides of the double bond to form the polymer known as gutta-perchaMore kinked, which complicates alignment, allows for mobility of one chain with respect to another, and gives natural rubber its elastomeric characterMore linear and crystallizes more readily. Consequently, harder, more brittle, and less elastic than natural rubber MANUFACTUREA series of “V” shaped or concentric cuts are made on the bark for the collection of milky juice in Areca palm conic receptacles. The juice is put into a pot and boiled with a little water to prevent its hardening on exposure to air. It is then boiled and kneaded under running water to remove particles of wood and bark; rolled into sheets to expel the air enabling it to dry quickly. It is placed in a revolving masticator and heated until it is fit for use. The chemical method of coagulation is by the addition of alcohol and creosote mixture (20:1), ammonia, limewater, or caustic soda.[] Obach's technique
In crude form, its composition is made of Gutta (75%–82%), Alban (14%–16%), Fluavil (4%–6%), and also tannin, salts, and saccharine. The elasticity of GP and its plasticity at elevated temperature is determined by Gutta. Alban does not seem to have any harmful effect on the technical properties of GP. Fluavil is a lemon-yellow, amorphous body, having the composition (C10H16O). When it occurs in gutta in larger quantities it renders this material brittle. It is relatively easy to make GP sticks as not much of precision is required. However, to make endodontic cones, the precision of standardization has to be maintained. It requires a special technology where all ingredients are blended and passed through the specification molds running under high vacuum suction or by injection molding and hand rolling.[,] CHEMICAL PHASES OF GUTTA-PERCHAC.W Bunn in the year 1942, reported that the GP polymer could exist in two distinctly different crystalline forms, which he termed “alpha” and “beta” modifications. These forms were “trans” isomer, differing only in single bond configuration and molecular repeat distance, and hence could be converted into each other. The “alpha” form occurs in the tree, which is the natural form. Most of the commercially available products are in the “beta” form. When the alpha form is heated >65°C, it becomes amorphous and melts. If this amorphous material is cooled rapidly, β form recrystallizes whereas if it is cooled extremely slowly (0.5°C/h), α form recrystallizes. The beta form becomes amorphous when heated at 56°C, which is a considerable 9° less than the melting point of the alpha form and the factor determining the melting point of “alpha” and “beta” GP is the rate of cooling which, in turn, controls the extent and character of crystallinity in the material formed [Table 2].[] Table 2Characteristics PhasesPropertiesAlpha (α) formBrittle at room temperature Gluey, adhesive and highly flowable when heated (lower viscosity) Example: Thermoplasticised gutta-percha used for warm condensation obturation techniqueBeta (β) formStable and flexible at room temperature Less adhesive and flowable when heated (high viscosity) Example: Commercially available gutta-percha used for cold condensation obturation techniquesGamma (γ) formSimilar to α- form, unstable PHYSICAL AND THERMO-MECHANICAL PROPERTIESGP is a thermoplastic and viscoelastic material which is temperature sensitive. At ranges of ambient room temperature, it exists in a stiff and solid state. It becomes brittle on prolonged exposure to light and air due to oxidation. It becomes soft at 60°C and it melts around 95°C–100°C with partial degradation. Decrease in temperature increase the strength and resilience and vice versa, especially when temperature exceeds 30°C.[] The physical properties of tensile strength, stiffness, brittleness, and radiopacity depend on the organic (GP polymer and wax/resins) and inorganic components (zinc oxide and metal sulfates). Zinc oxide increases brittleness, decreases percentage elongation and ultimate tensile strength.[] An account of the tensile strength of GP gives a reliable measure of its properties than compressive tests. Materials with the predominant property of ductility do not exhibit repeatable values for compression on account of resulting complicated stress patterns. The property of viscoelasticity is critical during condensation of GP in obturation procedures which permits plastic deformation of the material under continuous load causing the material to flow.[] The transformation temperatures of dental GP are 48.6°C–55.7°C for the β-to the α-phase transition, and 59.9°C–62.3°C for the α-to the amorphous phase transition, depending on the specific compound; heating dental GP to 130°C causes physical changes or degradation.[] An account of average values of few physical properties of some clinically usable GP points from various manufacturers is tabulated below. However, continuous modifications have been attempted over the years by the addition of various materials to improve the properties to result in better clinical performance [Table 3].[] Table 3Physical properties of Gutta percha Physical propertiesAverage valuesYield strength1000-1300 psiResilience40-80 in/lbTensile strength1700-3000 psiElastic modulus15,500-28,000 psiFlexibility0.07-0.12 in/lbElongation (%)170-500 PHYSICAL FORMS OF GUTTA-PERCHA
It is eugenol-free, self-polymerizing filling system in which the gutta percha in powder form is combined with a resin sealer in one capsule. It exhibits viscoelastic property of thixotropism and therefore has a better flow under shear stress which, in turn, provides good sealing ability. MODIFICATIONS OF GUTTA PERCHAAttempts have been made to obtain optimum seal and therapeutic effects by addition of various materials [Figure 1]. ![An external file that holds a picture, illustration, etc. Object name is JCD-22-216-g001.jpg](https://https://i0.wp.com/www.ncbi.nlm.nih.gov/pmc/articles/PMC6632621/bin/JCD-22-216-g001.jpg) Types of modified gutta percha Surface modified gutta perchaOne of the drawbacks of GP is lack of true adhesion. Hence, improvization for enhanced adaptability of GP has been attempted by surface modification with the following materials.
Medicated gutta-percha
Nanoparticles enriched gutta-perchaThe era of nanotechnology has turned into the best innovation in the fields of health sciences and innovation. Nano is derived from the Greek word “υαυος” which means dwarf, and it is the science of producing functional materials and structures in the range of 0.1 nm to 100 nm. Nano particulates show higher antibacterial action on account of their polycationic or polyanionic nature, which expands their applications in various fields. Nanodiamond-gutta-percha composite biomaterialsNanodiamond-GP composite embedded with nanodiamond amoxicillin conjugates was developed which could reduce the likelihood of root canal reinfection and enhance the treatment outcomes. NDs are carbon nanoparticles that are roughly 4μ - 6nm in diameter. It is a biocompatible platform for drug delivery, and they have demonstrated antimicrobial activity. Due to the ND surface chemistry, a broad-spectrum antibiotic, such as amoxicillin, can be adsorbed to the surface facilitating the eradication of residual bacteria within the root canal system after completion of obturation. The homogeneous scattering of NDs all through the GP matrix increases the mechanical properties, which enhance the success rate of conventional endodontic therapies and reduce the need for additional treatments, including retreats and apical surgeries.[] Silver nanoparticles coated gutta-perchaSilver (Ag) ions or salts possess sustained ion release, long-term antibacterial activity, low toxicity, good biocompatibility with human cells and low bacterial resistance. Dianat and Ataie have introduced nanosilver gutta-percha in an attempt to upgrade the antibacterial effect of GP, where the standard GP is coated with nanosilver particles. It demonstrates a significant antibacterial effect against E. faecalis, Staphylococcus aurous, Candida albicans, and E. coli.[] CLINICAL CONSIDERATIONSDisinfection of gutta-perchaHandling, aerosols, and physical sources during the storage process can contaminate GP. The conventional process in which moist or dry heat is used cannot sterilize GP because this may cause irreversible physical or chemical alteration to the structure. Rapid chairside chemical disinfection is needed as the amount of GP points needed cannot be predicted beforehand. Sodium hypochlorite, glutaraldehyde, alcohol, iodine compounds, and hydrogen peroxide have been tried as GP cones disinfectant. The time ranges from a few seconds to substantial periods for these substances to kill microorganisms. NaOCl at 5.25% concentration is an effective agent for a rapid high disinfection level of GP cones. 2% CHX kills all vegetative forms in a short period but did not eliminate Bacillus subtilis spores within the times tested.[] 2% peracetic acid solution is effective against some microorganisms in biofilms on GP cones at 1 min of exposure.[] Herbal extracts such as lemon grass oil, basil oil, and obicure tea extract, are probable alternatives for chairside disinfection of GP cones and have shown good results.[] Ethanolic extracts of Neem, Aloe vera, and Neem + Aloe Vera have been seen to be successful in decontaminating GP cones against E. coli and S. aureus (common contaminants of GP cones).[] Removal of gutta-perchaGP solvents are used during retreatment or solvent based obturation technique as attempt in complete mechanical removal may cause perforation, straightening of canals or change in the internal anatomy compromising the tooth and treatment outcome. Benzene and carbon tetrachloride have been discontinued as solvents due to their toxicity. Others include eucalyptol oil, chloroform, methylchloroform, and xylene. The eucalyptol oil does not effectively dissolve GP at room temperature and has to be heated to act relatively fast. Hence, it not widely used. Chloroform is preferred due to volatility, cost, availability, better odor, and compatibility with zinc oxide-eugenol-based root canal sealers. Trichloroethylene, cineole, orange oil, Coe Paste Remover, halothane, anise oil, anethole, bergamot oil, terpineol in cineole, chlorobutanol in cineole, methoxyflurane, and diethyl ether have been tried and tested.[] BIOLOGICAL PROPERTIES AND TISSUE INTERACTIONCross-reactivityGP and gutta-balata are derived from the same botanical family as the rubber tree, and related to latex. It is reported that occasionally in the short supply of GP, the manufacturers add some amount gutta-balata or synthetic trans-polyisoprene to the GP cones which is not disclosed. It is seen that raw gutta-balata releases proteins that cross-react with Hevea latex and the use of a gutta-balata-containing product could potentially place a high latex allergic patient at risk for an allergic reaction even when proper instrumentation and obturation techniques are used to confine the material within the root canal system.[] Reaction of dental pulpGP has been used as a temporary restorative material owing to its ease of placement and removal. The teeth become sensitive after its insertion into the dentin. Some of the teeth were extracted in an experimental study, and the histologic picture showed pathologic reaction in the pulp tissue, which changed with increasing observation period. The most typical reactions were:
Reaction of connective tissueGP has been the least irritating root canal filling material till date. Fibrous encapsulation, calcification, and foreign-body reactions are some of the common responses to GP extruded into the periapical tissues. Small amounts of plasticizers, age resisters, coloring agents, and other additives do not play a major role in influencing the irritational qualities of GP cones. An inflammatory reaction is found only when an irritating material made up a significant percentage of the cone, as in calcium hydroxide enriched GP points. Therefore, the use of other additives should be kept to optimum levels.[] Reaction of gingival fibroblast and epithelial tumor cellsIncreased connective tissue invagination with better healing of periradicular lesions have been attributed to calcium hydroxide and chlorhexidine-containing GP. Some authors described the destruction of epithelial tumor cells if present in periradicular lesions. Direct exposure of cells to the above materials has shown changes in cell morphology. The release of prostaglandin has been described as a helpful marker of inflammatory processes in pulp tissue. Conventional GP points have nonsignificant effect on the prostaglandin release by gingival fibroblasts. On contrary, some studies have shown that GP points containing calcium hydroxide or chlorhexidine, led to an inhibition of gingival fibroblast growth. Exposure of epithelial tumor cell cultures to the various tested materials led to morphological cell irregularities and influenced the proliferation patterns.[] ScaffoldsGP materials are primarily used for obturation, their interaction with living tissues is still being studied. Polybutadiene, a polymer with similar chemistry to PI, the base material of GP induces differentiation of dental pulp stem cells (DPSC), when its properties were modified by ZnO nanoparticles and dexamethasone. However, the mechanical strength and roughness imparted by the nanoparticles contributed to promoting differentiation of DPSC placed in contact with the material surfaces. It is probable that in addition to obturation, GP nanocomposites can act as scaffolds for dental tissue regeneration.[] MERITS AND DEMERITS OF GUTTA-PERCHATable 4 Merits and Demerits of gutta percha. OTHER USES OF GUTTA-PERCHAAssessment of pulp statusThermal stimulation is a standard means of assessing the vitality of teeth and hot GP has conventionally been the most popular. As controlled temperature is difficult to attain, it is imperative that heated GP should not be in contact with the tooth surface for more than 3–5 s, else may result in damage of an otherwise healthy pulp. Rickoff et al. showed that GP used as above-increased pulp temperature only <2°C for <5 s of application – a temperature change that is unlikely to cause pulp damage.[] Tracing sinus tractGP points are used to trace through sinus tracts to locate the source of infection and the offending tooth. Studies have indicated that GP is beneficial as a diagnostic adjunct and can be precise within 3 mm from the lesion. A medium-sized cone (size 25–40) has been found satisfactory due to its stiffness and ease of placement.[] Manual dynamic irrigationGP points are used for manual agitation of irrigants in the root canal to improve the cleansing ability of debriding and disinfecting solutions to remove the smear layer. TemporizationThe base plate and temporary stopping GP are used for this purpose after intra coronal tooth preparation and for double seal during endodontic interappointment periods. However, zinc oxide eugenol cements provide a better seal than GP. Hence GP for this purpose should be used discretely.[] Assessment of intracoronal tooth preparationAssessment of intracoronal tooth preparation was used to check undercuts in tooth preparation requiring indirect intracoronal restorations. Markers for orthodontic and prosthetic implant placementThe use of guides for radiographic evaluation and surgical placement of dental implants can improve the final outcome of treatment for patients receiving implants. To aid in the determination of the ideal site for the implant, guides with markers are useful. A material to be used as a guide during a computed tomography scan, should contain no metal to eliminate the possibility of scatter. Since GP fulfills this criterion, possesses radiopacity and can be formed to a desired shape, it is the material of choice for this purpose.[] CONCLUSIONIt can be concluded that the availability, ease of manipulation, chemical inertness, and cost effectiveness of GP along with newer techniques which are easy to adapt in clinical use have made this material indispensable in the field of endodontics. |