Hyaluronic Acid Combined with Ozone in Dental Practice
<p>Search strategy flow chart of studies selected from databases (Scopus, Embase, Google Scholar, PubMed, Web of Science). Reports excluded for lack of data.</p> "> Figure 2
<p>Figure shows a graph representing the risks of bias in various aspects of an analysis. The risks are coded in three colors: green for “low risk of bias”, and red for “high risk of bias”. In general, most categories show a low risk of bias (in green), except for the participant and staff blinding and the outcome assessment blinding, where there is a significant percentage of a high risk of bias (in red).</p> "> Figure 3
<p>Risk of bias. The image shows a table assessing the risk of bias in different categories (D1–D5) for various studies. The categories include bias from the randomization process, deviations from the intended intervention, missing outcome data, outcome measurement, and selection of reported outcomes. The judgments are coded with symbols: green (+) indicates low risk of bias, yellow (−) represents some concerns, red (×) indicates high risk, blue (?) indicates no information, and gray shows non-applicability.</p> ">
Abstract
:1. Introduction
2. Materials and Methods
3. Results
3.1. Quality Assessment and Risk of Bias
3.2. In the Battle Against Gingivitis
3.3. Chronic Periodontitis: A New Frontier
3.4. Surgical Frontiers and Implant Surgery
3.5. The Healing Touch on Oral Ulcers
4. Discussion
5. Conclusions
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Conflicts of Interest
References
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Criteria | Inclusion | Exclusion |
---|---|---|
Language | Studies published in English | Studies published in other languages |
Study Design | Human-controlled trials (randomized controlled trials, clinal trails) | Literature reviews, technical notes, letters to editors, instructional courses |
Population | Human subjects with dental conditions | Animal studies, in vitro research |
Intervention | Use of hyaluronic acid (HA) and ozone in treating gingivitis, ulcers, wounds, gingival recession | Studies not involving HA or ozone in dental treatment |
Outcome Measures | Histological or clinical evaluations of the impact of hyaluronic acid in dental disease contexts | Studies without clinical or histological evaluations |
Publication Type | Primary research articles | Non-primary research (e.g., opinion pieces, conference abstracts) |
Date Restrictions | No restriction on publication year | None |
Study Topic | Focus on HA and ozone’s effectiveness in oral health treatments | Focus on unrelated medical conditions or treatments |
PICO Component | |
---|---|
Participants | Healthy participants with no restrictions on age and sex with gingival recession, periodontitis, oral ulcers, surgery wounds |
Intervention | Application of HA combined with OT in conjunction with surgical procedures |
Comparison | The same surgical procedures without HA and OT or substitute |
Outcomes | Pathology reduction |
Authors | Mean Age | Ha Group | Control Group | Type of Treatment | Parameters Evaluated | Clinical Evidence |
---|---|---|---|---|---|---|
Jentsch [2] | 50 male (17 ± 39 y) | 25 with use of HA-OT | 25 with placebo | Gel on gingivitis. | The study evaluated oral health through clinical indices (approximal plaque index, Turesky plaque index, papillary bleeding index) and crevicular fluid markers (peroxidase, lysozyme) initially and after 4, 7, 14, and 21 days. | The test group exhibited notable enhancements in plaque indices from day 4 and in PBI from day 7, outperforming the placebo group. |
Pistorius [16] | 60 mixed (32 ± 41 y) | 40 with use of HA-OT | 20 with reduced use of HA | Spray on gingivitis. | Clinical measurements including DMF-T index, API, sulcus bleeding index, PBI, and gingival crevicular fluid were recorded at the start, then after 3 and 7 days. | Clinical parameters were assessed initially, and then at 3 and 7 days. The HA group saw decreases in sulcus bleeding index at both time points, with significant drops in PBI values and gingival crevicular fluid. |
Badge [18] | 21 mixed (22 ± 34 y) | 11 with use of HA-OT | 10 with placebo | Gel in periodontal pocket. | A gingival biopsy for histopathological and immunohistochemical analysis, focusing on Ki-67 expression and inflammatory infiltrate evaluation, was conducted 30 days post-treatment. | Treatment with HA gel notably decreased the proliferation index of gingival epithelium and fibroblast cells. |
Sahayata [17] | 105 mixed | 50 with use of HA-OT | 50 with reduced use of HA and short follow-up | Gel in periodontal pocket. | Clinical parameters (API, GI, PBI) were assessed at 1, 2, and 4 weeks from baseline; microbiological parameters were checked at 4 weeks. | Significant improvements in GI and PBI were observed in the test group compared to others. At 4 weeks, all treatment groups saw a significant decrease in anaerobic Gram-negative bacilli and an increase in Gram-positive coccoid cells from baseline. |
Xu [19] | 20 mixed (48 ± 64 y) | 10 with use of HA-OT | 20 with placebo | Gel in periodontal pocket. | SFFR and sulcus bleeding index were measured initially and weekly up to 12 weeks; probing depth and clinical attachment level were checked at the start and at 6 and 12 weeks. Dentists collected subgingival plaque samples to identify specific bacteria at baseline and at 6 and 12 weeks. | This study showed an improvement of all clinical variables in both groups. There are no clinical and microbiological differences between test and control sites. |
Johannsen [20] | 11 mixed (23 ± 56 y) | 10 with use of HA-OT | 11 with use of placebo | Spray in periodontal pocket. | SFFR and sulcus bleeding index were measured initially and weekly up to 12 weeks; probing depth and clinical attachment level were checked at the start and at 6 and 12 weeks. Dentists collected subgingival plaque samples to identify specific bacteria at baseline and at 6 and 12 weeks. | There are no clinical and microbiological differences between test and control sites. |
Polepalle [21] | 36 mixed (30 ± 65 y) | 26 with use of HA-OT | 10 with use of reduced HA and short follow-up | Gel in periodontal pocket. | Bleeding on probing (BOP), API, probing pocket depth (PPD), and clinical attachment level (CAL) were assessed at baseline, 1, 4, and 12 weeks. Colony-forming units (CFU) per mL were assessed at baseline, after treatment, and after 2 weeks. | There was a significant reduction in BOP, API, PPD, and CAL in the test sites than control group. In the test sites there was also a significant reduction of CFUs. |
Gontiya [22] | 26 mixed (25 ± 55 y) | 20 with use of HA-OT | 6 with use of placebo | Gel on gingivitis. | Clinical parameters GI, PBI, PPD, and relative attachment level (RAL) evaluated at baseline (day 0) and weeks 4, 6, and 12. | The test sites showed statistically significant improvement in GI and PBI at 6 and 2 weeks compared to control sites. |
Rajan [23] | Not specified | 33 with use of HA-OT | Not specified | Gel on gingivitis. | The clinical parameters evaluated: GI, API, BOP, PPD, CAL at three appointments: before SRP, 4 weeks, and 12 weeks after SRP. | The test sites showed statistically significant improvement in GI and PBI at 6 and 2 weeks compared to control sites. |
Pilloni [24] | 19 mixed (15 ± 41 y) | 15 with use of HA-OT | 4 with use of placebo | Gel and spray in mild chronic periodontitis. | These clinical parameters were evaluated before treatment and repeated at 14 and 21 days: API, BOP, GI, probing attachment level (PAL). | HA gel treatment was more effective, reducing BOP by 92.7% and GI by 96.5%, compared to 75.8% and 79.0% in controls. Periodontitis reduction was significantly greater in the HA-treated area. |
Eick [25] | 42 mixed (41 ± 72 y) | 17 with use of HA-OT | 17 with use of placebo | Gel and spray in mild chronic periodontitis. | PD and CAL measurements were taken at the start, 3 months, and 6 months, with subgingival plaque and sulcus fluid samples collected for analysis. | The test sites showed statistically significant improvement in GI and PBI at 6 and 2 weeks compared to control sites. |
Chauhan [26] | 60 mixed (30 ± 65 y) | 30 with use of HA-OT | 30 with use of reduced HA | Gel and spray in mild chronic periodontitis. | PD and CAL measurements were taken at the start, 3 months, and 6 months, with subgingival plaque and sulcus fluid samples collected for analysis. | At 3 months, change in PPD and CAL was greater in the test group than the control group, but the difference was non-significant. |
Engstrum [27] | 15 mixed (23 ± 54 y) | 8 with use of HA-OT | 7 with use of placebo | Not specified. | PD and CAL measurements were taken at the start, 3 months, and 6 months, with subgingival plaque and sulcus fluid samples collected for analysis. | After 12 months, the test and control groups in surgery showed a bone height difference under 1 mm, visible only in radiographs. Both groups experienced bone height reduction post-scaling. Probing depth decreased as anticipated following surgery and SRP. |
Briguglio [7] | 15 mixed (23 ± 54 y) | 8 with use of HA-OT | 7 with use of placebo | Not specified. | PD and CAL measurements were taken at the start, 3 months, and 6 months, with subgingival plaque and sulcus fluid samples collected for analysis. | The use of hyaluronic acid in treating infrabony defects provided additional advantages, including improved clinical attachment levels, reduced probing depths, and enhanced predictability, compared to traditional open flap debridement methods. |
Bevilacqua [28] | 24 mixed (+-51 y) | 11 with use of HA-OT | 13 with use of placebo | Gel in moderate–severe chronic periodontitis. | Clinical variables assessed included API, BOP, CAL, PPD, calprotectin, MPO, and GCF volume on days 45 and 90. Calprotectin, MPO, and GCF quantities were measured at test and control sites on days 7 and 45. | At baseline and 45 days, the HA group showed a significant decrease in probing depth and BOP compared to the control group. Both groups experienced a notable reduction in calprotectin and myeloperoxidase per sample after 1 week, followed by an increase at 45 days. |
Karim [29] | 14 mixed (23 ± 34 y) | 7 with use of HA-OT | 7 with reduced use of HA | Gel in chronic periodontitis. | BOP, API, PPD, and CAL were assessed at baseline, 1, 4, and 12 weeks. CFU per mL was assessed at baseline, after SRP, and after 2 weeks. | The test sites showed significant improvements in BOP, API, PPD, and CAL compared to the control group, alongside a notable decrease in CFUs. |
Araujo Nobre [30] | 30 mixed (58.4 ± y) | 15 with use of HA-OT | 15 with use of CHX | Management of the implant platform and healing screw at implant uncovering with gel. | The clinical parameters evaluated: modified plaque index (mPlI), modified bleeding index (mBI), PPD in mL, suppuration (Sup), clinical implant mobility (mob). Both groups were followed up for 6 months, and the clinical observations were performed on day 10 and at 2, 4, and 6 months post-surgery. | HA and CHX effectively supported peri-implant health. The HA group had significantly better modified bleeding index at the second check. At 6 months, CHX showed potentially superior outcomes in modified plaque and bleeding indices. |
Galli [31] | 8 mixed (36 ± 67 y) | 4 with use of HA-OT | Not specified | Post-implant wound management with gel. | The PPDs, gingival recession, and CAL were evaluated before treatment and after 1 year. | After 1 year the following results were found: PPD reduction, gingival recession increase, and CAL gain. |
Ballini [32] | 19 mixed (43.8 ± y) | 19 with use of EHA-OT | Not specified | Post-implant wound management with gel. | The PPDs, gingival recession, and CAL were evaluated before treatment and after 1 year. | Clinical results showed a mean gain of CAL (gCAL) of 2.6 mm at the treated sites, confirmed by radiographic evaluation. |
Koray [33] | 34 mixed (23 ± y) | 34 with use of HA-OT | 34 with use of BnzHCl | Management of bilateral extraction of the lower octaves with HA gel or BnzHCL spray. | Swelling was measured with a tape and trismus by the maximum interincisal opening. Evaluations occurred on the surgery day and 2 and 7 days post-surgery. | The patients with HA gel experienced statistically significant results for the swelling and trismus values compared to those with the BnzHCl spray. |
Romeo [34] | 49 mixed (45.5 ± y) | 31 with use of HA-OT | 18 with use of placebo | Management of excisional biopsy with HA gel. | The lesion area was measured after surgery (T0) and after 7 days (T1). A percentage healing index (PHI) was calculated, indicating healing extension in 7 days. | Not specified. |
Kumar [21] | Not specified | 1 with use of HA-OT | Not specified | Gel on gingival recession. | RD, PPD, and CAL were tracked at baseline and then at 1, 3, 6, 12, and 24 weeks post-surgery. | Despite the lack of statistical significance, the experimental group’s root coverage was observed to be more clinically stable than that of the control group at 24 weeks. |
Lee [35] | 50 mixed (40 y) | 33 with use of HA-OT | 17 with placebo | Gel on oral ulcers in Behçet’s disease. | Subjective assessment: number of ulcers, healing period and VAS; objective assessment: number and maximal size of ulcers. | Ulcer inspection revealed a 57.6% reduction in numbers and a 78.8% decrease in area among patients. Post-treatment, significant improvements were seen in swelling and local heat. |
Nolan [6] | 106 mixed (37 y) | 60 with use of HA-OT | 56 with use of placebo or reduced level of HA | Gel on oral ulcers. | Average ulcer count, ulcer history over 7 days, patients experiencing ulcers in this period, and treatment assessment scores ranging from very good to not recorded. | Both groups noted quick discomfort relief from ulcers, lasting around 30 min before reverting towards initial levels. Ulcer counts slightly dropped over 7 days, regardless of treatment. By day 5, the HA group reported significantly fewer ulcers compared to the placebo group. Despite new ulcers appearing in both groups during the study, the HA group saw a notably lower incidence of new ulcers by day 4. |
Lopez [36] | 1 male (32 y) | 1 with use of HA-OT | Not present | Application of HA gel in intracrestal sinus lift. | The filling volume obtained was measured with a comparative software program and using an ellissoid formula. This technique allows the surgery to be performed in a way that is both minimally traumatic and invasive, fully careful of the membrane, and represents a viable alternative to those surgical techniques for crestal sinus lift currently in use. | Not specified. |
Schwartz [37] | 26 mixed (45 ± y) | 26 with use of HA-OT | Not present | Application of HA gel and bone graft in lateral sinus lift. | All 32 sinus lifts succeeded, with cone beam scans showing bone height increasing from 2.84 mm pre-treatment to 15.2 mm post-treatment. | This study confirmed the hypothesis that new bone formation is graft dependent alone or in combination with other materials. |
Weindl [8] | 45 mixed (23 ± 45 y) | 25 with use of HA-OT | 20 with use of placebo | Treatment of gingival recession with use of HA gel. | Recession depths in the first, third, and sixth month were 1.82 ± 0.442, 1.31 ± 0.47 mm, and 0.91 ± 0.29, respectively, which showed a significant reduction. | Within the limitations of the present study, the data obtained by periodic assessment of the clinical parameters indicate the use of amnion membrane and hyaluronic acid, and proper technique may thus be the panacea for root coverage procedures. |
Gorski [38] | 24 mixed (34 ± y) | 24 with use of HA-OT | Not applicable | Use of HA gel in the treatment of multiple gingival recession using the modified coronally advanced tunnel technique (MCAT) combined with subepithelial connective tissue graft (SCTG), with or without cross-linked hyaluronic acid (HA). | No significant improvement in root coverage was observed because of adding HA. After 6 months, mean root coverage (MRC) was 85% for SCTG + HA group and 83% for SCTG group (p = 0.9819). Complete root coverage (CRC) was observed in 91% (test) and 93% (control) of the cases (p = 0.9001). | Both treatments were similarly effective in treating multiple GRs and led to comparable improvements in clinical parameters. However, application of HA improved the appearance of soft tissue texture. |
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Rosa, A.; Pujia, A.M.; Arcuri, C. Hyaluronic Acid Combined with Ozone in Dental Practice. Biomedicines 2024, 12, 2522. https://doi.org/10.3390/biomedicines12112522
Rosa A, Pujia AM, Arcuri C. Hyaluronic Acid Combined with Ozone in Dental Practice. Biomedicines. 2024; 12(11):2522. https://doi.org/10.3390/biomedicines12112522
Chicago/Turabian StyleRosa, Alessio, Alberto Maria Pujia, and Claudio Arcuri. 2024. "Hyaluronic Acid Combined with Ozone in Dental Practice" Biomedicines 12, no. 11: 2522. https://doi.org/10.3390/biomedicines12112522
APA StyleRosa, A., Pujia, A. M., & Arcuri, C. (2024). Hyaluronic Acid Combined with Ozone in Dental Practice. Biomedicines, 12(11), 2522. https://doi.org/10.3390/biomedicines12112522