- Research article
- Open access
- Published:
Assessment of the half-life of cationic periodontal pocket irrigation
BMC Oral Health volume 20, Article number: 10 (2020)
Abstract
Background
The concentration and persisting time of antimicrobial agents in the periodontal pockets are important factors for their antimicrobial efficacy. Increased clearance time in the periodontal pocket is a significant criterion for the selection of intrapocket irrigants. The aim of this study was to estimate the clearance time of a cationic agent from the periodontal pocket.
Methods
Thallium-201(Tl-201) was chosen as a tracer to simulate the clearance of cationic substance because of its electrical activity. Twenty patients with periodontitis and probing depths 6 to 9 mm were included in this study. In each patient, 3 Mega Becquerel (MBq) of Tl-201 were inserted into the periodontal pocket. Dynamic imaging was performed and clearance of radioactivity was measured.
Results
Clearance of radioactivity was 67.1 ± 16.9, 83.1 ± 13.9, 90.4 ± 10.4, 93.39 ± 8.0% at 30, 60, 90 and 120 min, respectively. Half-life of wash-out was determined as 20.3 ± 10.2 min.
Conclusion
The results of this study demonstrate that the half-life of the cationic solution applied subgingivally was approximately 20 min and labelling of oral irrigants with radiotracers may be used to determine their clearance in further research.
Background
Antimicrobial agents for the support of periodontal treatment are given via rinsing, irrigation, systemic administration, and local application using sustained and controlled delivery devices [1,2,3,4,5,6].
Oral rinsing is an inefficient method for the introduction of mouth rinses into the periodontal pockets [7, 8]. Therefore, various subgingival irrigation devices (syringe, jet irrigator with a cannula and ultrasonic instrument) have been studied [9,10,11]. However, Hardy et al. reported that if the irrigating tip was inserted 3 mm subgingivally, complete irrigation was achieved, regardless of pocket depth [12].
Increased clearance time (wash-out from the pocket) in the sulcus is an important aim of selected intrapocket irrigants. According to Oosterwaal et al., crevicular fluid flow affects clearance of the irrigant [13]. Different methods have been reported for evaluation of the effectiveness of drugs used in periodontal treatment. These are the filter paper strip, paper point, fluorometric technique, optical density reading by spectrophotometer and nuclear medicine techniques [13,14,15,16,17].
Some medications bind to the soft and hard tissue walls of the pocket and prolong their clearance time from the periodontal pocket [18]. This property is called substantivity. Some antimicrobial agents show this property because of electrostatic interactions. Chlorhexidine digluconate, which is used as an irrigation and rinsing antimicrobial agent, is a cationic molecule binding to anionic substrates (hydroxyapatite, pellicle, salivary glycoproteins, and mucous membranes) with electrostatic interactions [8, 19]. Due to technical limitations, the evaluation of irrigation substances’ substantivity is difficult in the subgingival region Radioactive tracers facilitate the evaluation of periodontal pocket clearance due to the high sensitivity of small volumes of radiolabelled substance to detection remote from the pocket, and they also allow the measurement of clearance in real time [16].
The aim of the present study was to assess the clearance time of a cationic substantive molecule from the periodontal pocket whether it was slow or not. Tl-201, an easily detectable cationic radioactive agent, was chosen to calculate the clearance time.
Methods
The research reported in the paper was undertaken in compliance with the Helsinki Declaration and the protocol of this study was previously approved by the Research Ethics Committee of Ondokuz Mayis University (2009/101). The aim of the investigation was fully explained to patients and informed consent was obtained from all patients.
Study population
Twenty non-smoking patients (5 females and 15 males) aged between 42 and 56 with periodontitis were included in this study. Twenty periodontal pockets (probing pocket depths 6 to 9 mm) belong to single rooted teeth were used. Minimum required sample size was calculated 16 at an alpha value of 0.05. Therefore, 20 periodontal pockets were included in this study.
Clinical examination
One hour before the study with Tl-201, subgingival curettage was carried out on each periodontal pocket, and only one pocket per subject was used. The margins of the periodontal pockets were sealed with retraction cord to prevent the abrupt overflow of Tl-201 before the dynamic imaging was performed. Retraction cord surrounding the teeth had some space between two ends as small as needle entry. When we did not use retraction cord, most of the oral cavity was contaminated by Tl-201. Therefore, clear image of related area could not be obtained. Four MBq (unit of radiation activity) of Tl-201 was diluted with isotonic solution and three MBq radioactive agent was prepared to obtain better images. Three MBq of Tl-201 in isotonic solution (sterile and non-pyrogenic) was inserted into the periodontal pocket. Firstly, a syringe with a blunted needle of 0.4 mm diameter was placed apically in the pocket and approximately 0,015–0,02 cc radioactive agent injected until it became visible at the margin of the pocket. The retraction cord was then removed and dynamic imaging performed with the patient in the supine position under a gamma camera (GE starcam 4000i XC/T) equipped with a low energy general-purpose collimator. The energy window of the Tl-201 was 72 keV ± 10% and the matrix size was 128 × 128. Acquisition was begun immediately after the insertion of Tl-201 (final molarity strength was 2,02 ± 10− 8 mol/L) into the pocket. Clearance of radioactivity from the insertion site was measured at 20-s intervals for 20 min.
Half-life of cationic pocket irrigation
A quantitative analysis of the kinetic frame was performed for each patient. The region of interest was drawn over the injection site and the time-activity curve was established for each periodontal pocket using mono-exponential curve fitting. The following equation obtained from the curve was used to determine the rate of decline of activity in pockets at 30, 60, 90 and 120 min, and also the half- life of wash-out:
y = m (e-kt).
where.
y: the fractional liquid retention at time (t).
m: the constant.
k: the emptying rate in minutes− 1.
Pocket depths, clearance at 30, 60, 90 and 120 min and half- life of wash-out were reported as mean ± standard deviation (SD).
Results
Mean probing pocket depth was 6.85 ± 0.93 mm. Half-life and clearance of 100% of initial radioactivity at 30, 60, 90 and 120 min were calculated from the curves. Clearance of radioactivity was 67.1 ± 16.9, 83.1 ± 13.9, 90.4 ± 10.4, 93.39 ± 8.0% at 30, 60, 90 and 120 min, respectively. Half- life of wash-out was determined as 20.3 ± 10.2 min. Some pockets (patient no 4, 9, 12, 15) have shorter clearance time than other pockets (Table 1).
Fig. 1 (Patient no. 14) shows 1 min per frame of dynamic images of Tl-201 activity in the periodontal pocket. Time-activity curve obtained from the same patient shows relatively slow wash-out from the pocket (Fig. 2). Scintigraphic images and time-activity curves show decreased activities in the periodontal pockets as a function of time
(Patient no. 14) Dynamic images
(Patient no. 14) Time-activity curve
Discussion
This study was designed to investigate the clearance time of a cationic substance in real time, but not in the context of therapy. The thallium used in this study is in series IIIA of the periodic table and is readily available as radioactive Tl-201 that has a half life of 73 h. For over 30 years, it has been used in nuclear cardiology studies to assess myocardial perfusion and viability [20, 21]. The current study used Tl-201 to evaluate the clearance of the cationic solution because it is an easily detectable and positively charged substance.
The results of this study demonstrated that most of the cationic substance inserted into the periodontal pocket was washed out within 2 h and some subjects (patient no 4, 9, 12, 15) had shorter clearance time. This could have been caused by periodontal disease severity or by stimulation of fluid flow during tracer insertion and/or subgingival curettage.
The half-life of fluorescein gel persistence in the periodontal pocket was 12.5 min [13] and chitosan persistence using gamma scintigraphy was 41.5 min [16]. In the current study, 80.6% of the radiotracer had cleared from the periodontal pocket at 60 min and the half-life was calculated as 20.3 min. However, this short persistence time could not be enough to achieve a therapeutic concentration. Stimulation of crevicular fluid flow, presence of blood components [7, 22] and dilution of drugs applied in the pocket [23] may limit the effectiveness of subgingival irrigation. A single irrigation of periodontal pockets has limited effects on periodontal healing after scaling and root planning [7]. In contrast, Lander et al. reported that a single subgingival irrigation with 0.2% chlorhexidine digluconate changed the subgingival flora for up to 4 weeks [24].
Goodson estimated that 0.5 μL of periodontal pocket fluid is replaced 40 times/hour [25]. Stabholz et al. reported that subgingival irrigation with 0.12% chlorhexidine digluconate did not exhibit long-lasting substantivity [17]. Oosterwaal et al. reported that when chlorhexidine digluconate gel was applied into the periodontal pocket three times within 10 min, antimicrobial activity could be increased, but this effect continued for only a short time [26, 27].
Subgingival penetration may be limited by the presence of calculus deposits [28, 29]. Hence, subgingival curettage was performed before the application of Tl-201 into the periodontal pockets. However this may have decreased the clearance time because of increasing of gingival crevicular fluid flow.
Boyd et al. inserted the irrigator tip to one-half the depth of the pocket and suggested that the pocket location or the number of roots did not affect the depth of penetration [30]. Single rooted teeth were included in the current study, because we wanted to use approximately similar area and volume of periodontal pockets. Blunt needle was inserted to the base of the pocket and then the substance was injected into the pocket in this study like in the study of Needleman et al. [16].
In this study, only one pocket per subject was used. The reason is that if two or more periodontal pockets were treated simultaneously, the real clearance time of the periodontal pockets could not be calculated exactly due to superposition of activities.
Conclusion
The results of this study demonstrate that the half-life of cationic solution applied subgingivally is relatively short. In clinical practice, cationic liquid substances applied to the periodontal pocket do not have enough substantivity because of their relatively fast clearance. Further studies could be directed toward improving the substantivity of oral irrigants, and labelling of oral irrigants with radiotracers may used to determine their clearance in further research.
Availability of data and materials
The datasets used and/or analysed during the current study are available from the corresponding author on reasonable request.
Abbreviations
- Tl-201:
-
Thallium-201
- MBq:
-
Mega Becquerel
- SD:
-
Standard deviation
References
Herrera D, Matesanz P, Bascones-Martinez A, Sanz M. Local and systemic antimicrobial therapy in periodontics. J Evid Based Dent Pract. 2012;12:50–60.
Lecic J, Cakic S, Janjic Pavlovic O, Cicmil A, Vukotic O, Petrovic V, Cicmil S. Different methods for subgingival application of chlorhexidine in the treatment of patients with chronic periodontitis. Acta Odontol Scand. 2016;74:502–7.
Da Rocha HA, Silva CF, Santiago FL, Martins LG, Dias PC, De Magalhaes D. Local drug delivery systems in the treatment of periodontitis: a literature review. J Int Acad Periodontol. 2015;17:82–90.
Stabholz A, Nicholas AA, Zimmerman GJ, Wikesjo UME. Clinical and antimicrobial effects of a single episode of subgingival irrigation with tetracycline HCl or chlorhexidine in deep periodontal pockets. J Clin Periodontol. 1998;25:794–800.
Tomasi C, Wennstrom JL. Locally delivered doxycycline as an adjunct to mechanical debridement at retreatment of periodontal pockets: outcome at furcation sites. J Periodontol. 2011;82:210–8.
Walker CB, Godowski KC, Borden L, Lennon J, Nango S, Stone C, Garrett S. The effects of sustained release doxycycline on the anaerobic flora and antibiotic-resistant patterns in subgingival plaque and saliva. J Periodontol. 2000;71:768–74.
Shiloah J, Hovious LA. The role of subgingival irrigations in the treatment of periodontitis. J Periodontol. 1993;64:835–43.
Greenstein G, Berman C, Jaffin R. Chlorhexidine. An adjunct to periodontal therapy. J Periodontol. 1986;57:370–7.
Braatz L, Garrett S, Claffey N, Egelberg J. Antimicrobial irrigation of deep pockets to supplement nonsurgical periodontal therapy. II Daily irrigation J Clin Periodontol. 1985;12:630–8.
Ravishankar PL, Venugopal K, Nadkerny P. Effect of Tetracycline Hydrochloride and Spiramycin Sub Gingival Irrigation with Pulsated Jet Irrigator in Chronic Periodontitis Patients: A Clinical Study. J Int Oral Health. 2015;7:102–7.
Nosal G, Scheidt MJ, O'Neal R, Van Dyke TE. The penetration of lavage solution into the periodontal pocket during ultrasonic instrumentation. J Periodontol. 1991;62:554–7.
Hardy JH, Newman HN, Strahan JP. Direct irrigation and subgingival plaque. J Clin Periodontol. 1982;9:57–65.
Oosterwaal PJM, Mikx FHM, Renggli HH. Clearance of a topically applied fluorescein gel from periodontal pockets. J Clin Periodontol. 1990;17:613–5.
Deinzer R, Mossanen BS, Herforth A. Methodological considerations in the assessment of gingival crevicular fluid volume. J Clin Periodontol. 2000;27:481–8.
Needleman IG, Smales FC, Martin GP. An investigation of bioadhesion for periodontal and oral mucosal drug delivery. J Clin Periodontol. 1997;24:394–400.
Needleman I, Mather SJ, Martin GP, Sobnack R. Periodontal pocket clearance by gamma scintigraphy in human volunteers. J Clin Periodontol. 2000;27:904–9.
Stabholz A, Kettering J, Aprecio R, Zimmerman G, Baker PJ, Wikesjo UME. Retention of antimicrobial activity by human root surfaces after in situ subgingival irrigation with tetracycline HCL or chlorhexidine. J Periodontol. 1993;64:137–41.
Greenstein G, Tonetti M. The role of controlled drug delivery for periodontitis.The research, science and therapy Committee of the References American Academy of periodontology. J Periodontl. 2000;71:125–40.
Freitas LB, Vassilakos N, Arnebrant T. Interactions of chlorhexidine with salivary films adsorbed at solid/liquid and air/liquid interfaces. J Periodontal Res. 1993;28:92–7.
Lebowitz E, Greene W, Fairchild R. Thallium-201 for medical use. I J Nuclear Med. 1975;16:151–5.
Shen TY, Chang MC, Hung GU, Kao CH, Hsu B. Prognostic Value of Functional Variables as Assessed by Gated Thallium-201 Myocardial Perfusion Single Photon Emission Computed Tomography for Major Adverse Cardiac Events in Patients with Coronary Artery Disease. Acta Cardiol Sin. 2013;29:243–50.
Krück C, Eick S, Knöfler GU, Purschwitz RE, Jentsch HF. Clinical and microbiologic results 12 months after scaling and root planing with different irrigation solutions in patients with moderate chronic periodontitis: a pilot randomized trial. J Periodontol. 2012;83:312–20.
Oosterwaal PJM, Mikx FHM, van den Brink ME, Renggli HH. Bactericidal concentration of chlorhexidine-digluconate, amine fluoride gel and stannous fluoride gel for subgingival bacteria tested in serum at short contact times. J Periodontal Res. 1989;24:155–60.
Lander PE, Newcomb GM, Seymor GJ, Powell RN. The antimicrobial and clinical effects of a single subgingival irrigation of chlorhexidine in advanced periodontal lesions. J Clin Periodontol. 1986;13:74–80.
Goodson JM. Pharmacokinetic principles controlling efficacy of oral therapy. J Dent Res. 1989;68:1625–32.
Oosterwaal PJ, Mikx FH, Van’t Hof MA, Renggli HH. Short- term bactericidal activity of chlorhexidine gel, stannous fluoride gel and amine fluoride gel tested in periodontal pockets. J Clin Periodontol. 1991;18:97–100.
Oosterwaal PJ, Mikx FH, Van’t Hof MA, Renggli HH. Comparison of the antimicrobial effect of the application of chlorhexidine gel, amine fluoride gel, stannous fluoride gel in debrided periodontal pockets. J Clin Periodontol. 1991;18:245–51.
Eakle W, Ford C, Boyd RL. Depth of penetration in periodontal pockets with oral irrigation. J Clin Periodontol. 1986;13:39–44.
Flemmig TF. Supragingival and subgingival irrigation. In: Newman MG, Takei HH, Caranza FA, editors. Caranza’s Clinical Periodontology. 9th ed. Saunders: Saunders Company Philadelphia; 2002. p. 615–21.
Boyd RL, Hollander BN, Eakle WS. Comparison of a subgingivally placed cannula oral irrigator tip with a supragingivally placed standart irrigator tip. J Clin Periodontol. 1992;19:340–4.
Acknowledgements
The authors thank Gregory T. Sullivan of the University of Queensland in Brisbane, Australia for proofreading an earlier version of this manuscript.
Funding
The work was not supported by any organization.
Author information
Authors and Affiliations
Contributions
TK and MS developed the concept and design of this study. TK, MS, IK, BK and SA have taken a role in data collection and analysis. TK and MS wrote the manuscript. US and GA revised the manuscript. All authors read and approved the final manuscript. TK revised the manuscript in response to reviewers’and editors’ comments.
Corresponding author
Ethics declarations
Ethics approval and consent to participate
This study was approved by the Research Ethics Committee of Ondokuz Mayis University (2009/101) and written informed consent was obtained from the patients.
Consent for publication
Not applicable.
Competing interests
The authors declare that they have no competing interests.
Additional information
Publisher’s Note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Rights and permissions
Open Access This article is distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution, and reproduction in any medium, provided you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made. The Creative Commons Public Domain Dedication waiver (http://creativecommons.org/publicdomain/zero/1.0/) applies to the data made available in this article, unless otherwise stated.
About this article
Cite this article
Kirtiloglu, T., Keskiner, I., Sahin, M. et al. Assessment of the half-life of cationic periodontal pocket irrigation. BMC Oral Health 20, 10 (2020). https://0-doi-org.brum.beds.ac.uk/10.1186/s12903-019-0998-8
Received:
Accepted:
Published:
DOI: https://0-doi-org.brum.beds.ac.uk/10.1186/s12903-019-0998-8