This in-vivo study aim to evaluate effect of different irrigation activating techniques on Irrigant Penetration Depth and Microbial Reduction in root Canals
Chemomechanical preparation with removal of infected tissues and microbial biofilms is the corner stone of root canal treatment. Since mechanical instrumentation alone cannot adequately disinfect root canals, complete cleaning and shaping involves irrigation with chemicals together with mechanical instrumentation. In addition to shaping the root canal, the aim of chemical-mechanical preparation of root canals is to eliminate vital or necrotic tissue, microorganisms and their products, and dentin debris that result from instrumentation. However, the complexity of root canal anatomy together with microbial infection hinder this purpose. Primary endodontic infection is characterized by the presence of a wide range of microbial diversity dominated by anaerobes. The polymicrobial profile of pulp infection involves both Gram-positive and Gram-negative bacterial species. Besides, the apical third of the root canal system typically has a complex morphology and is difficult to clean. So, it is important to bring irrigants into contact with the entire canal surfaces along its total micro anatomic complexity for effective action especially in the apical portions . Irrigating solutions used during endodontic handling act through direct contact with the targeted bacteria. However, irrigants have inadequate penetration depth. It is highly desirable that chemical substances selected as endodontic irrigants have antimicrobial and organic tissue dissolution properties besides serving in the debridement of the root canal system and not being toxic to the tissues .Sodium hypochlorite (NaOCl) has been the gold standard for irrigation because of its ability to dissolve organic matter and high antimicrobial potential. Conventional needle irrigation is the most commonly employed technique for delivering irrigants into the root canal system. However, the disadvantage of conventional needle irrigation is its passive action, and inability to deliver solutions into the narrow anatomical features of the root canal system. Despite the high success rates of root canal treatment, reducing the bacterial load below the level that is required to assure healing has become the accepted goal. Hence, several irrigant activation systems have been developed to increase the effectiveness of irrigation by providing energy within the canal to disperse and move the irrigant around the canal system in anticipation of them removing biofilm more effectively. Therefore, various activation and agitation systems have been introduced to improve the irrigation penetration and effectiveness. These systems include manual dynamic agitation, sonic, passive ultrasonic, photon initiated photoacoustic streaming (PIPS), laser, XP-endo Finisher file, and Easy-Clean (EC). The XP-endo Finisher file is a new rotary file presented to be used after root canal instrumentation as a final step in order to improve irrigant penetration and root canal cleaning and disinfection. It is made from a special nickel-titanium (NiTi) MaxWire alloy Hence, it possesses the shape memory effect when inserted into the canal (M-phase changed to A-phase) and exhibits superelasticity during canal preparation. EC is an irrigation activating device, using an acrylonitrile butadiene styrene plastic instrument designed to produce vigorous intracanal fluid agitation.It has advantages of promoting agitation along the whole length of the instrument with no risk of deforming the canal walls. There are many methods to evaluate penetration of irrigant solution into root canal but most them laboratory or ex-vivo using dye marker as Rhodamine B stain and methylene blue, while other radiopaque marker as Iohexol are used clinically. Radiopaque contrast media as Iohexol can be used to assess the effect of various irrigation activating techniques on irrigant penetration into root canals in vivo as they can be seen in dental radiographs. Iohexol has the advantage of being a low osmolality agent that it is readily available in a sterile, pyrogen-free, nontoxic solution. It is widely used for angiocardiographic studies, thoracic and lumbar myelography, and in contrast enhancement for brain computed tomography and imaging of salivary glands. Activation of irrigantion was considered one important method of bacterial reduction beside decreasing biofilm formation in root canals. on the other hand, it was reported that the activation protocols facilitate the disinfection of anatomical complexities and dentinal tubules. According to the current knowledge, there is few studies concerning the effect of different irrigation activation techniques on enhancing irrigant penetration into the apical third of root canals and on reducing microbial infection, so this study aims to evaluate irrigant penetration depth and microbial reduction after using different irrigation activation techniques.
Study Type
INTERVENTIONAL
Allocation
RANDOMIZED
Purpose
TREATMENT
Masking
DOUBLE
Enrollment
30
The first microbial sample (S1) will be taken from the root canal immediately after access cavity preparation and before chemomechanical preparation.Samples will be subjected to bacterial viable count using blood agar. After complete chemomechanical preparation, a second microbial samble (S2) will be taken and managed the same way as S1.After irrigation activation protocol by matching gutta percha master cone , S3 will be collected from each root canal and managed as S1, S2 to evaluate effect of activation techniques on microbial reduction ,canals will be dried with a matching paper point then 1 mL of Iohexol (omnipaque) contrast media will be injected 2mL shorter than WL and activated by a matching gutta percha master cone , a digital radiographic image will be obtained for each tooth with the same angulation as that for WL and then the distance between WL and maximum irrigant penetration will be measured and recorded using SIDEXIS-XG software.
Faculty of Dentistry
Tanta, Egypt
RECRUITINGmeasurment of penetration depth of irrigant
measurment the difference between the working length and penetration depth of irrigant
Time frame: at the same 1 day visit
measurment of bacterial reduction following different irrigation activating techniques
collection of 3 samples followed by culturing on blood agar and counting to calculate percentage of bacterial reduction
Time frame: 24-28 hours after culturing
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The first microbial sample (S1) will be taken from the root canal immediately after access cavity preparation and before chemomechanical preparation.Samples will be subjected to bacterial viable count using blood agar. After complete chemomechanical preparation, a second microbial samble (S2) will be taken and managed the same way as S1.After irrigation activation protocol by XP-endo Finisher used in continuous rotation for 1 minute , S3 will be collected from each root canal and managed as S1, S2 to evaluate effect of activation techniques on microbial reduction ,canals will be dried with a matching paper point then 1 mL of Iohexol (omnipaque) contrast media will be injected 2mL shorter than WL and activated by a matching gutta percha master cone , a digital radiographic image will be obtained for each tooth with the same angulation as that for WL and then the distance between WL and maximum irrigant penetration will be measured and recorded using SIDEXIS-XG software.
after access cavity preparation and before chemomechanical preparation.Samples will be subjected to bacterial viable count using blood agar. After complete chemomechanical preparation, a second microbial samble (S2) will be taken and managed the same way as S1.After irrigation activation protocol by EasyClean system activation , S3 will be collected from each root canal and managed as S1, S2 to evaluate effect of activation techniques on microbial reduction ,canals will be dried with a matching paper point then 1 mL of Iohexol (omnipaque) contrast media will be injected 2mL shorter than WL and activated by a matching gutta percha master cone , a digital radiographic image will be obtained for each tooth with the same angulation as that for WL and then the distance between WL and maximum irrigant penetration will be measured and recorded using SIDEXIS-XG software.