Abstract
Objectives
Evaluation of an ex vivo porcine model to investigate the influence of periodontal instrumentation on soft tissue.
Material and methods
In each of 120 pig mandibles, one molar tooth was chosen at random and instrumented. For subgingival debridement, two different low abrasive airpolishing powders (glycine d90 = 25 μm, erythritol d90 = 14 μm, n = 30 teeth each), curets, and a piezoelectric ultrasonic scaler were used (n = 30 teeth each). Thirty teeth in 30 other mandibles served as the untreated control. Gingival biopsies were histologically assessed for destruction using a four-graded scale.
Results
The porcine model was deemed suitable for the planned investigation. Hand instrumentation and ultrasonic scaling caused higher tissue damage than both low abrasive airpolishing modes (Fisher’s exact test, p = 0.0025). Glycine powder led to less, yet non-statistical noticeable gingival changes compared to erythritol-based powder (Fisher’s exact test, p = 0.39).
Conclusion
An animal model using pig jaws may be used as a preliminary model to analyze histological effects of periodontal instrumentation in advance of studies performed in human tissues. Among the techniques assessed, low abrasive airpolishing (LAA) caused the smallest tissue damage.
Clinical relevance
To avoid gingival damage using LAA, histological observations of gingival tissue are needed. Since numerous powders for LAA have been developed and it may be expected that additional products will follow, it appears to be useful to establish ex vivo animal models to prove the powders safety.
Avoid common mistakes on your manuscript.
Introduction
In supportive periodontal therapy (SPT), biofilm removal plays a pivotal role. In most treatment settings, hand instruments or oscillating scalers are used to fulfill this task [1]. As an alternative, low abrasive airpolishing (LAA) has been developed to make the treatment easy while allowing gentle debridement [2]. Potential harmful effects of airpolishing on oral tissues have been addressed earlier [3,4,5,6,7,8,9]. Nevertheless, data comparing the effect of various low abrasive media on oral soft tissue is rare, as since the inauguration of LAA in 2003, numerous new products such as powders consisting of erythritol, tricalcium phosphate, trehalose, aluminium trioxide, and hydroxyapatite have been introduced.
Using live animals or working on human patients in research to date leads to a rise in costs and complicates obtaining new knowledge. Scrutinizing animal models instead may facilitate determination of safety and efficacy of new therapies [10,11,12]. Among animal tissues, porcine buccal gingiva obtained from abattoirs bears excellent histological resemblance when compared to human oral tissue [13]. Therefore, the intention of this study was to establish and evaluate the usability of a porcine periodontal treatment model for LAA and to histologically evaluate the influence of various modes of instrumentation.
Material and methods
Instrumentation and biopsy
Pig mandibles were obtained from Erlangen abattoir, processed within 6 h after sacrifice and kept under constant temperature of 8 °C. The buccal aspect of one molar was chosen randomly and the jaw was fixed in a mounting device allowing controlled instrumentation. Each treatment was applied to another mandible and one tooth per mandible was analyzed to maintain an independent set of the observations.
Four modes of instrumentation were investigated. Group A: LAA using glycine powder with a mean grain size of d90 of 25 μm (EMS Perio Powder, EMS, Nyon, Switzerland). Group B: LAA using erythritol powder with mean grain size of d90 of 14 μm (EMS Plus Powder). In groups A and B, an airpolishing unit type EMS Air Flow Master was used with a standard handpiece. The tip was held at a distance of 5 mm to the gingival tissue in a constantly sweeping manner for 5 s with the jet aimed into the gingival crevice as if removal of subgingival biofilm was intended. In group C, a piezoelectric scaler with a slim tip at medium power and water setting was used with the tip angulated parallel to the root surface at a pressure of approx. 1 N for 10 s (EMS Piezon Master Tip PS8LL). In group D, hand instruments using a 7/8 Gracey Curet (Deppeler, Rolle, Switzerland) were applied with five strokes with a pressure of approximately 3 N [14]. Untreated biopsy samples served as negative control (group E).
Following instrumentation, the soft tissue alongside the tooth was removed using a 15c blade scalpel. Incisions were performed avoiding contact of the blade to the oral sulcular or junctional epithelium (Fig. 1).
The tissue was stored in 4% formalin in 0.1 mM PO4-buffered saline (PBS, pH = 7.4). Formalin was washed out with water for 24 h. Samples were then dehydrated by increasing alcohol concentration. Alcohol was displaced by inserting samples into cedar/paraffin mixture, saturated for 24 h at 60 °C in three passes in paraffin, and embedded in block forms. Serial sections of the biopsies (thickness 8 μm) were applied to slides and stained with azan and hematoxylin eosin. Light microscopic evaluation criteria were applied to compare between test and control groups using signs of cell and tissue damage of the gingival epithelium or the oral junctional epithelium and the lamina propria. The blinded investigator assigned the sections according to the present state of the biopsies using a graded scoring system [4] (Table 1).
Statistical analysis
Based on previous investigations [3, 4], 30 samples per group were considered to be sufficient to allow a meaningful data interpretation. To assure independent samples and avoid clustered data, each treatment was applied to a single tooth, and each tooth resp soft tissue specimen was taken from a new pig jaw.
During study initiation, the pathologist was trained by performing double scorings on 15 randomly chosen samples. The weighted kappa coefficient was calculated to determine the reproducibility of the readings resp the level of intra-rater agreement [15].
Standard descriptive statistical analyses were performed. Categorical variables are reported as absolute and relative frequencies. The global dependency of mode of therapy and degree of tissue damage was evaluated using Fisher’s exact test. Pairwise comparisons between the treatment groups were performed using again Fisher’s exact tests (SAS software 9.4 for Windows, SAS Institute, Cary, USA). Due to the explorative nature of the study, all p values are not confirmatory and have to be interpreted in an exploratory sense. Consequently, no significance levels were defined and no adjustment for multiplicity was performed. Therefore, small p values were considered as statistically noticeable.
Data availability
The raw data used for the statistical analysis may be accessed at www.osf.io . using the following reference:
Petersilka, G. (2017, October 6). Effect of Low Abrasive Airpolishing on the Gingiva using an Ex Vivo Porcine Model. Retrieved from osf.io/xeayd.
Results
Specimen retrieval as well as histological proceeding was possible without unwanted or unexpected effects. For the performed double assessment, the weighted kappa coefficient was estimated being 0.69 and indicated a good agreement between the two measurements. The overall impact of the various modes of instrumentation on the soft tissue is depicted in Fig. 2. A general difference could be detected between the various modes of instrumentation (p = 0.0025).
As seen by the frequency of specimens with a code two and three, hand instrumentation (p = 0.0067) and ultrasonics (p = 0.0071) generated noticeable tissue damage followed by erythritol (p = 0.037) and glycine (p = 0.25) if compared to untreated control. Among LAA, use of glycine showed a lower frequency of relevantly damage if compared to erythritol, but this difference was not statistically noticeable (p = 0.39). None of the specimens in the glycine group was given a damage score of two or three. Interestingly, 63% of specimens in this groups (n = 19) were scored undamaged while 11 were given a damage score of 1.
Hand instrumentation led to the most pronounced damage with four specimens showing a destruction degree of code three. Ultrasonics was slightly less traumatic than hand instrumentation with only one tissue section showing a destruction with complete removal of epithelium and basal membrane leading to exposition of connective tissue (degree three). However, the observed difference was not statistically noticeable (p = 0.35).
In the untreated control group, six samples (29%) exhibited a score of 1 indicating a slight damage of the superficial epithelium. All modes of instrumentation allowed debridement without relevant signs of tissue damage as indicated by the accumulated number of specimens with scores of 0 and 1 leaving the basal membrane undamaged (Fig. 2). Representative images of biopsies are depicted in Fig. 3.
Discussion
To date, it seems worthwhile to develop model situations reflecting the human clinical situation as much as possible on a responsible ethical standard by avoiding vivisection [3, 16]. Within our model, we found results in accordance and comparable to those recognized in human studies performed earlier, such as hand instrumentation being the most traumatic mode of instrumentation [4]. For the use of glycine powder in humans, Petersilka et al. found in 2008 a frequency of 30% of specimens with undamaged epithelium and 70% of specimens with superficial damage. For the glycine powder approach used here, the corresponding frequencies of damage degrees were 40 and 60% respectively. Nevertheless, the overall magnitude of tissue damage appeared to be slightly lower when compared to that of the human situation. One reason for that might be the slightly different thickness of the porcine gingival epithelium [13] as well as its degree of keratinization.
From a clinical point of view, the data generated may underline the overall low potential of soft tissue damage generated by LAA. It was interesting to note, however, that the two low abrasive powders assessed showed minor differences in their abrasive behavior. In conclusion, within its limits, the chosen ex vivo porcine model seems suitable for further assessing and comparing the influence of periodontal debridement procedures on gingival tissue. It appears to be justified to use this approach in further research.
References
Petersilka GJ, Ehmke B, Flemmig TF (2002) Antimicrobial effects of mechanical debridement. Periodontol 2000 28(1):56–71
Petersilka GJ (2011) Subgingival air-polishing in the treatment of periodontal biofilm infections. Periodontol 2000 55(1):124–142
Kozlovsky A, Artzi Z, Nemcovsky CE, Hirshberg A (2005) Effect of air-polishing devices on the gingiva: histologic study in the canine. J Clin Periodontol 32(4):329–334
Petersilka G, Faggion CM Jr, Stratmann U, Gerss J, Ehmke B, Haeberlein I, Flemmig TF (2008) Effect of glycine powder air-polishing on the gingiva. J Clin Periodontol 35(4):324–332
Kontturi-Närhi V, Markkanen S, Markkanen H (1989) The gingival effects of dental airpolishing as evaluated by scanning electron microscopy. J Periodontol 60(1):19–22
Mishkin DJ, Engler WO, Javed T, Darby TD, Cobb RL, Coffman MA (1986) A clinical comparison of the effect on the gingiva of the Prophy-Jet and the rubber cup and paste techniques. J Periodontol 57(3):151–154
Hunter KM, Holborow DW, Kardos TB, Lee-Knight CT, Ferguson MM (1989) Bacteraemia and tissue damage resulting from air polishing. Br Dent J 167(8):275–288
Bühler J, Amato M, Weiger R, Walter C (2016) A systematic review on the effects of air polishing devices on oral tissues. Int J Dent Hyg 14(1):15–28
Herr ML, DeLong R, Li Y, Lunos SA, Stoltenberg JL (2017) Use of a continual sweep motion to compare air polishing devices, powders and exposure time on unexposed root cementum. Odontology 105(3):311–319
Arnold CR, Kloss F, Singh S, Vasiljevic D, Stigler R, Auberger T, Wenzel V, Klima G, Lukas P, Lepperdinger G, Gassner R (2017) A domestic porcine model for studying the effects of radiation on head and neck cancers. Oral Surg Oral Med Oral Pathol Oral Radiol 123(5):536–543
Schwarz F, Sculean A, Engebretson SP, Becker J, Sager M (2015) Animal models for peri-implant mucositis and peri-implantitis. Periodontol 2000 68(1):168–181
Sculean A, Chapple IL, Giannobile WV (2015) Wound models for periodontal and bone regeneration: the role of biologic research. Periodontol 2000 68(1):7–20
Sa G, Xiong X, Wu T, Yang J, He S, Zhao Y (2016) Histological features of oral epithelium in seven animal species: as a reference for selecting animal models. Eur J Pharm Sci 81(1):10–17
Zappa U, Smith B, Simona C, Graf H, Case D, Kim W (1991) Root substance removal by scaling and root planing. J Periodontol 62(12):750–754
Landis JR, Koch GG (1977) The measurement of observer agreement for categorical data. Biometrics 33(1):159–174
Sweatman J (2003) Good clinical practice: a nuisance, a help or a necessity for clinical pharmacology? Br J Clin Pharmacol 55(1):1–5
Funding
The work was supported by EMS, Nyon Switzerland. EMS covered the costs for the pig jaws, the debridement equipment, and the histological evaluation.
Author information
Authors and Affiliations
Corresponding author
Ethics declarations
Conflict of interest
Gregor Petersilka declares that he has no conflict of interest. Ralph Heckel declares that he has no conflict of interest. Raphael Koch declares that he has no conflict of interest. Benjamin Ehmke declares that he has no conflict of interest. Nicole Arweiler declares that she has no conflict of interest. Nicole Arweiler and Gregor Petersilka have been lecturing and receiving speakers’ fees on a freelance basis for EMS in continuing education courses and Gregor Petersilka also for consultancies.
Ethical approval
This article does not contain any studies with humans or live animals performed by any of the authors. The veterinary ethics committee of the district council of Lower Franconia stated that a permission to use pig mandibles was not necessary since they are considered as non-edible offal.
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.
About this article
Cite this article
Petersilka, G., Heckel, R., Koch, R. et al. Evaluation of an ex vivo porcine model to investigate the effect of low abrasive airpolishing. Clin Oral Invest 22, 2669–2673 (2018). https://doi.org/10.1007/s00784-018-2536-5
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s00784-018-2536-5