Osseointegration of implants with superhydrophilic surfaces in rats with high serum levels of nicotine

Pinotti, Felipe Eduardo; Aroni, Maurício Andrés Tinajero; Oliveira, Guilherme José Pimentel Lopes de; Silva, Bruno Luís Graciliano; Marcantonio Junior, Elcio; Marcantonio, Rosemary Adriana Chiérici

doi:10.1590/0103-6440202305096

Abstract

This study aimed to evaluate the effect of nicotine administration on the osseointegration of a superhydrophilic implants surface on rat tibiae. Thirty-two rats were used and divided into 2 groups according to the administration or not of nicotine: HH - Installation of implants with superhydrophilic surfaces in healthy animals; and HN - Installation of implants with superhydrophilic surfaces in animals subjected to nicotine administration. The animals were euthanized 15 and 45 days after implant placement (n = 8). Osseointegration was assessed by means of biomechanical analyses (removal torque), microcomputed tomography (volume of bone around the implants- %BV/TV), and histomorphometry (bone-implant contact -%BIC and the bone area between implant threads -%BBT). The animals subject to the nicotine administration presented lower removal torque than the control animals at the 45-day period (21.88 ± 2.80 Ncm vs. 17.88 ± 2.10 Ncm). The implants placed in the control rats presented higher %BIC (54.26 ± 6.59% vs. 39.25 ± 4.46%) and %BBT (50.57 ± 5.28% vs. 32.25 ± 5.24%) than the implants placed in nicotine animals at 15-day period. The nicotine administration reduces the osseointegration at 15 days, however, the superhydrophilic surface equalized the osseointegration in nicotine-exposed animals compared with healthy animals after 45 days of implant placement.

Key Words:
implant surface; osseointegration; smoke

Resumo

O objetivo deste estudo foi avaliar o efeito da administração de nicotina na osseointegração de implantes com superfície modificada por jateamento de oxidos e ataque ácido instalados em tíbia de ratos. Foram utilizados 32 ratos que foram divididos em 2 grupos de acordo com a administração ou não de nicotina: HH - Instalação de implantes com superfícies superhidrofílicas em animais sadios; e HN - Instalação de implantes com superfícies superhidrofílicas em animais submetidos à administração de nicotina. Os animais foram eutanasiados 15 e 45 dias após a colocação do implante (n = 8). A osseointegração foi avaliada por meio de análises biomecânicas (torque de remoção), microtomografia (volume de osso ao redor dos implantes - %BV/TV) e histomorfometrica (contato osso-implante -%BIC e área óssea entre roscas do implante -%BBT). Os animais submetidos à administração de nicotina apresentaram menor torque de remoção do que os animais controle no período de 45 dias (21,88 ± 2,80 Ncm vs. 17,88 ± 2,10 Ncm). Os implantes colocados nos ratos controle apresentaram maiores %BIC (54,26 ± 6,59% vs. 39,25 ± 4,46%) e %BBT (50,57 ± 5,28% vs. 32,25 ± 5,24%) do que os implantes colocados nos animais submetidos a administração de nicotina no período de 15 dias. A administração de nicotina prejudicou a osseointegração no período de 15 dias. Entretanto, a superfície superhidrofílica equalizou a osseointegração em animais expostos à nicotina em comparação com animais saudáveis após 45 dias da colocação do implante.

Introduction

Oral rehabilitation with osseointegrated implants has achieved good outcomes in several clinical conditions regardless of the size of the rehabilitation ¹1 .Galindo-Moreno, P; Nilsson, P; King, P; Worsaae, N; Schramm, A; Padial-Molina, M; et al. Clinical and radiographic evaluation of early loaded narrow-diameter implants: 5-year follow-up of a multicenter prospective clinical study. Clin Oral Implants Res. 2017;28(12):1584-91.. However, some host factors may directly interfere with host bone tissue metabolism, which can negatively affect the implant osseointegration process and impair the long-term maintenance of the implants²2. Khandelwal, N; Oates, TW; Vargas, A; Alexander, PP; Schoolfield, JD; Alex McMahan, C. Conventional SLA and chemically modified SLA implants in patients with poorly controlled type 2 diabetes mellitus--a randomized controlled trial. Clin Oral Implants Res. 2013;24(1):13-9..

Smoking is one of the most important risk factors related to tooth loss³3. Helal ,O; Gostemeyer, G; Krois, J; Fawzy, El; Sayed, K; Graetz, C; Schwendicke, F. Predictors for tooth loss in periodontitis patients: Systematic review and meta-analysis. J Clin Periodontol. 2019;46(7):699-712.^,⁴4. Javed, F; Rahman, I; Romanos, GE. Tobacco-product usage as a risk factor for dental implants. Periodontol 2000. 2019;81(1):48-56.. Previous clinical studies have shown that smokers are approximately 2 to 3.6 times more likely to lose teeth³3. Helal ,O; Gostemeyer, G; Krois, J; Fawzy, El; Sayed, K; Graetz, C; Schwendicke, F. Predictors for tooth loss in periodontitis patients: Systematic review and meta-analysis. J Clin Periodontol. 2019;46(7):699-712.. Thus, this population would have a greater need to replace lost dental elements with osseointegrated implants. However, this same habit is also related to problems in achieving good osseointegration, as well as in relation to the host's resistance to the microbial challenge that can result in peri-implant diseases⁴4. Javed, F; Rahman, I; Romanos, GE. Tobacco-product usage as a risk factor for dental implants. Periodontol 2000. 2019;81(1):48-56.. Indeed, previous clinical studies have been shown that the dental implants lost is 5.64 times higher in smokers⁵5. Windael, S; Vervaeke, S; De Buyser, S; De Bruyn, H; Collaert, B. The Long-Term Effect of Smoking on 10 Years' Survival and Success of Dental Implants: A Prospective Analysis of 453 Implants in a Non-University Setting. J Clin Med. 2020;9(4). while the occurrence of periimplantitis is 2.63 higher in smokers compared with non-smokers⁶6. Costa, FO; Lages, EJP; Cortelli, SC; Cortelli, JR; Mattos-Pereira, GH; Lima, RPE; et al. Association between cumulative smoking exposure, span since smoking cessation, and peri-implantitis: a cross-sectional study. Clin Oral Investig. 2022.. These deleterious effects have been related to the high number of cigarettes used per day and heavy smokers (>10 cigarettes per day) are in a higher risk for implants lost ⁴4. Javed, F; Rahman, I; Romanos, GE. Tobacco-product usage as a risk factor for dental implants. Periodontol 2000. 2019;81(1):48-56.. Furthermore, these outcomes are related to the effects of smoking on the inhibition of macrophages, decreased chemotaxis of inflammatory cells, and decreased platelet aggregation, which impair the host's immune-inflammatory response⁷7. Davies, CS; Ismail, A. Nicotine has deleterious effects on wound healing through increased vasoconstriction. BMJ. 2016;353:i2709..

Among the numerous toxic substances present in cigarettes, nicotine stands out for being the substance related to addiction among its consumers⁸8. Fowler, CD; Turner, JR; Imad Damaj, M. Molecular Mechanisms Associated with Nicotine Pharmacology and Dependence. Handb Exp Pharmacol. 2020;258:373-93., as well as to important changes related to the healing of tissues(9, 10). Nicotine interferes with the activity of fibroblasts¹⁰10. Wong, LS; Green, HM; Feugate, JE; Yadav, M; Nothnagel, EA; Martins-Green, M. Effects of "second-hand" smoke on structure and function of fibroblasts, cells that are critical for tissue repair and remodeling. BMC Cell Biol. 2004;5:13. and osteoblasts⁹9. Ma, L; Zheng, LW; Sham, MH; Cheung, LK. Uncoupled angiogenesis and osteogenesis in nicotine-compromised bone healing. J Bone Miner Res. 2010;25(6):1305-13., generating less bone formation around the implants and decreasing their osseointegration¹¹11. Ghanem, A; Abduljabbar, T; Akram, Z; Vohra, F; Kellesarian ,SV; Javed, F. A systematic review and meta-analysis of pre-clinical studies assessing the effect of nicotine on osseointegration. Int J Oral Maxillofac Surg. 2017;46(4):496-502..

One approach used to accelerate the osseointegration process in individuals with challenging systemic conditions is the modification of the implant surfaces¹²12. Pinotti, FE; de Oliveira, G; Aroni, MAT; Marcantonio RAC; Marcantonio, E Jr;. Analysis of osseointegration of implants with hydrophilic surfaces in grafted areas: A Preclinical study. Clin Oral Implants Res. 2018;29(10):963-72.^,¹³13. Buser, D; Broggini, N; Wieland, M; Schenk, RK; Denzer ,AJ; Cochran, DL; et al. Enhanced bone apposition to a chemically modified SLA titanium surface. J Dent Res. 2004;83(7):529-33.. These physicochemical surface modifications aim to increase the stability of the blood clot that serves as a guide for the beginning of the osseointegration process, promoting an increase in their osteoconduction properties¹⁴14. Lang, NP; Salvi, GE; Huynh-Ba, G; Ivanovski, S; Donos ,N; Bosshardt, DD. Early osseointegration to hydrophilic and hydrophobic implant surfaces in humans. Clin Oral Implants Res. 2011;22(4):349-56.^,¹⁵15. Sartoretto, SC; Alves, AT; Resende, RF; Calasans-Maia ,J; Granjeiro, JM; Calasans-Maia, MD. Early osseointegration driven by the surface chemistry and wettability of dental implants. J Appl Oral Sci. 2015;23(3):279-87.. A surface modified by sandblasting and acid etching and maintained in sodium chloride solution has been shown to accelerate and improve the osseointegration process. These events have been related to the maintenance of the oxide layers promoted by the presence of the sodium chloride solution being in contact with the surface until the moment of implant installation, which maintains the oxide layer and increases the surface wettability¹²12. Pinotti, FE; de Oliveira, G; Aroni, MAT; Marcantonio RAC; Marcantonio, E Jr;. Analysis of osseointegration of implants with hydrophilic surfaces in grafted areas: A Preclinical study. Clin Oral Implants Res. 2018;29(10):963-72.^,¹³13. Buser, D; Broggini, N; Wieland, M; Schenk, RK; Denzer ,AJ; Cochran, DL; et al. Enhanced bone apposition to a chemically modified SLA titanium surface. J Dent Res. 2004;83(7):529-33.^,¹⁴14. Lang, NP; Salvi, GE; Huynh-Ba, G; Ivanovski, S; Donos ,N; Bosshardt, DD. Early osseointegration to hydrophilic and hydrophobic implant surfaces in humans. Clin Oral Implants Res. 2011;22(4):349-56.. In this context, this superhydrophilic surface may be an interesting alternative to improve the osseointegration in smokers.

Thus, the objective of this study was to evaluate the effect of the nicotine administration on the osseointegration of an implant surface modified by sandblasting, acid etching and maintained in an isotonic solution (superhydrophilic) in rat tibiae.

Materials and methods

Study design and ethical considerations

This study was approved by the Ethics Committee of Animal Use in Research (CEUA-44/2017). In this study, thirty-two male rats (Rattus norvegicus, albinus variation: Holtzman) of approximately 3 months of age, with a body mass between 200-300 grams, were kept in the Vivarium of the our institution. The animals were fed solid commercial rat chow and had access to water ad libitum before and throughout the experimental period in an environment with controlled water, light and temperature.

The 32 animals were randomly divided into 2 groups with 16 animals each, which were evaluated in two experimental periods (15 and 45 days), with 8 animals in each group. The groups were divided according whether the animals were subjected to challenge with nicotine: HH: Systematically healthy animal subjected to implant installation with a superhydrophilic surface created by sandblasting and acid etching and maintained in a sodium chloride solution (ACQUA Surface, Neodent®, Curitiba, PR, Brazil); HN: Animal that received nicotine administration and an implant with a superhydrophilic surface (ACQUA Surface, Neodent®, Curitiba, PR, Brazil).

Nicotine administration

Nicotine administrations were performed through daily subcutaneous applications every 12 hours in the dorsal region of the animals, starting 30 days before the surgical procedure. The animals received a diluted solution of nicotine of 5 mg/ml, which was administered a dose of 3 mg/kg¹⁶16. de Almeida, JM; de Moraes, RO; Gusman, DJ; Faleiros, PL; Nagata, MJ; Garcia, VG; et al. Influence of low-level laser therapy on the healing process of autogenous bone block grafts in the jaws of systemically nicotine-modified rats: A histomorphometric study. Arch Oral Biol. 2017;75:21-30.. The animals in the control group received administrations of saline solution at the same frequency as the animals subjected to the challenge with nicotine. The nicotine and saline solution administrations were maintained until the animals were euthanized.

Surgical Procedure

The animals were anesthetized by a combination of ketamine (Agener União Ltda, São Paulo, SP, Brazil) and xylazine (Rompum, Bayer SA, São Paulo, SP, Brazil). The implants (4 mm height and 2.2 mm diameter titanium implant, Acqua Implants, Neodent®, Curitiba, PR, Brazil) were placed in the rat tibiae through the application of a progressive sequence of drillers (2.0 mm spiral drill- Neodent®; Curitiba, PR, Brazil) with the aid of an electric motor, adjusted to 1200 rpm, under abundant irrigation with sterile saline solution. The implant was installed with the help of a digital key (Hexagonal digital key 1.2 mm - Neodent, Curitiba, PR, Brazil). Then, the soft tissues were sutured. The animals received, in a single dose, penicillin associated with streptomycin (Multibiotic Small, Vitalfarma, São Sebastião do Paraíso, MG, Brazil) and ketoprofen (Ketoflex; Mundo Animal, São Paulo, Brazil) intramuscularly. The animals were euthanized by an anesthetic overdose after 15 and 45 days of the implant’s placement. The tibiae were randomly separated, one of which was used for microcomputed tomographic and histomorphometric analyses, while the other was used for biomechanical analysis.

Biomechanical analysis

After euthanasia, the tibiae were stabilized in a small vice. A hexagonal wrench was connected to both the implant and a torque wrench (Tohnichi, model ATG24CN-S, Tokyo, Japan - with a graduated scale of 0.05 N/cm, measuring the strength from 3 to 24 Ncm), and anti-clockwise movement was performed with the objective of unscrewing the implant. The maximum peak required to move the implant was noted as the removal torque value (Ncm).

Microtomographic analysis

Tibiae that did not undergo biomechanical analysis were fixed in 4% paraformaldehyde for 48 hours and later stored in 70º alcohol. The samples were scanned by a microcomputed tomograph (Skyscan, Aatselaar, Belgium) with the following parameters: camera pixel: 12.45; X-ray tube power: 65 kVP, X-ray intensity: 385 µA, integration time: 300 ms, filter: Al-1 mm and voxel size: 18 µm³. The images were reconstructed, spatially repositioned and analysed by specific software (NRecon, Data Viewer, CTAnalyser, Aatselaar, Belgium). The region of interest (ROI) was defined as a circular region 0.5 mm around the entire diameter of the implant. This ROI was defined as the total volume (0.5 mm margin around the implants - 4.5 mm x 3.2 mm) (Figure 1A). The threshold used in the analysis was 25-90 shades of grey, and the values of the volume of mineralized tissue around the implants were obtained as a percentage (BV/TV%)¹²12. Pinotti, FE; de Oliveira, G; Aroni, MAT; Marcantonio RAC; Marcantonio, E Jr;. Analysis of osseointegration of implants with hydrophilic surfaces in grafted areas: A Preclinical study. Clin Oral Implants Res. 2018;29(10):963-72.. A trained examiner who was blinded to the experimental groups performed this FEP analysis.

Figure 1
Scheme of evaluation of the micro-CT and histomorphometric analysis. A) The region of interest (ROI) was defined as a circular region 0.5 mm around the entire diameter of the implant (Area between the two circles); B) The percentages of bone-implant contact (% BIC) (Delimited lines) and the bone area between turns (% BBT) (area inside the region) were evaluated separately in the first three threads of the implants.

Histomorphometric analysis

After scanning, the tibiae were dehydrated in a graded series of ethanol (60 - 100º), infiltrated, and polymerized in light-cured resin (Technovit 7200 VLC, Kultzer Heraus GmbH & CO, Wehrheim, Germany). The blocks containing the implant and bone tissue were cut at a central point using a cut and wear system (Exakt Apparatebeau, Hamburg, Germany). The sections were approximately 45 μm thick, stained with Stevenel blue associated with acid fuchsin and analysed under an optical microscope (DIASTAR - Leica Reichert & Jung products, Wetzlar, Germany) at 100X magnification. Histomorphometric evaluations were performed with ImageJ software (San Rafael, CA, USA). The percentages of bone-implant contact (% BIC) and the bone area between threads (% BBT) were evaluated separately in the first three threads of the implants (Figure 1B). A blinded and trained examiner (FEP) performed these analyses.

Sample size calculation

The sample size calculation was performed take in consideration that the %BIC is the primary variable of this study. The differences between the groups considered as relevant was 10%. Then, considering that the standard deviation expected for this analysis is 4.63 ¹²12. Pinotti, FE; de Oliveira, G; Aroni, MAT; Marcantonio RAC; Marcantonio, E Jr;. Analysis of osseointegration of implants with hydrophilic surfaces in grafted areas: A Preclinical study. Clin Oral Implants Res. 2018;29(10):963-72. and establishing the type I error at 0.05 and β power at 0.90, indicates that the minimum number of animals in each group is 8.

Statistical analysis

The distribution of the data generated in this study was assessed using the Shapiro-Wilk normality test. All data in this study were distributed according to normality; thus, parametric tests were applied for inferential analysis of the data. Comparison between the groups and between different periods within each group was performed using the unpaired t-test. GraphPad Prism 6 software (San Diego, CA, USA) was used to perform the statistical analysis, and all statistical tests were applied at a significance level of 5%.

Results

Biomechanical analysis

There was a progressive increase in the removal torque of the implants in the control animals over the 45-day period compared to the 15-day period (p <0.01). The animals subject to the nicotine administration presented lower removal torque than the control animals at the 45-day period (21.88 ± 2.80 Ncm vs. 17.88 ± 2.10 Ncm) (Figure 2).

Microcomputed tomographic analysis

There was a progressive increase in BV/TV% in all groups over the 45-day period compared to the 15-day period (p <0.001). However, there were no differences in BV/TV% between the control and nicotine animals (Figure 2).

Histomorphometric analysis

There was a progressive increase in the %BIC and %BBT values in all groups at the 45-day period compared to the 15-day period (p <0.001). In general, the implants placed in the control rats presented higher %BIC (54.26 ± 6.59% vs. 39.25 ± 4.46%) and %BBT (50.57 ± 5.28% vs. 32.258 ± 5.24%) than the implants placed in nicotine animals at 15-day period (Figure 2). Figure 3 shows representative images of the non-decalcified histological sections in all groups and experimental periods.

Figure 2
Representative graphs showed the mean and standard deviation of all the analysis performed in this study. **p<0.01; ***p<0.001- Differences between the control and nicotine animals; ##p<0.01; ###p<0.001- Intragroup differences regarding the experimental period - Unpaired t-test.

Discussion

The results of this study were encouraging regarding the use of implants with superhydrophilic surfaces due to the benefit of the osseointegration process since the %BIC and %BBT were similar in longer experimental periods (45-days). However, the osseointegration occurred slower in nicotine animals and this fact may influence on the loading protocols of dental implants.

The analysis of the removal torque, %BIC, and %BBT demonstrated that the animals subjected to nicotine application presented less implant locking, less bone-implant contact, and less bone between the threads of the implants. These findings corroborate previous results presented in the literature that demonstrated that nicotine and smoking impair the bone healing process in bone fractures¹⁷17. Hernigou, J; Schuind, F. Tobacco and bone fractures: A review of the facts and issues that every orthopaedic surgeon should know. Bone Joint Res. 2019;8(6):255-65., in skin, and in mucous membrane wounds⁷7. Davies, CS; Ismail, A. Nicotine has deleterious effects on wound healing through increased vasoconstriction. BMJ. 2016;353:i2709. due to a series of changes, both local and systemic in the body, including macrophage inhibition, decreased inflammatory cell chemotaxis, and decreased platelet aggregation, which impair the host's immune-inflammatory response⁴4. Javed, F; Rahman, I; Romanos, GE. Tobacco-product usage as a risk factor for dental implants. Periodontol 2000. 2019;81(1):48-56. .

Figure 3
Representative images of the non-decalcified histological sections in all groups and experimental periods. It was possible to observe a higher degree of osseointegration in control animals at the 15-day period (Black Arrows). The amount of bone in the vicinity of the implants was also more noted at the surfaces in control animals (*). On the other hand, more soft tissues were observed in nicotine groups (#).

Specifically, in bone tissue, nicotine has been shown to reduce osteogenesis by inhibiting the expression of BMP2 and VEGF⁹9. Ma, L; Zheng, LW; Sham, MH; Cheung, LK. Uncoupled angiogenesis and osteogenesis in nicotine-compromised bone healing. J Bone Miner Res. 2010;25(6):1305-13. and increasing vasoconstriction⁴4. Javed, F; Rahman, I; Romanos, GE. Tobacco-product usage as a risk factor for dental implants. Periodontol 2000. 2019;81(1):48-56., in addition to impairing the quality of blood clot formation⁷7. Davies, CS; Ismail, A. Nicotine has deleterious effects on wound healing through increased vasoconstriction. BMJ. 2016;353:i2709.. Previous studies have shown how the aforementioned effects negatively interfere with bone repair in different experimental models. A preclinical study showed that nicotine administration to rats harmed bone repair in areas grafted with autogenous bone¹⁶16. de Almeida, JM; de Moraes, RO; Gusman, DJ; Faleiros, PL; Nagata, MJ; Garcia, VG; et al. Influence of low-level laser therapy on the healing process of autogenous bone block grafts in the jaws of systemically nicotine-modified rats: A histomorphometric study. Arch Oral Biol. 2017;75:21-30.. A systematic review of preclinical studies has shown that animals subjected to nicotine administration presented a reduced bone-implant contact of implants compared to healthy animals¹¹11. Ghanem, A; Abduljabbar, T; Akram, Z; Vohra, F; Kellesarian ,SV; Javed, F. A systematic review and meta-analysis of pre-clinical studies assessing the effect of nicotine on osseointegration. Int J Oral Maxillofac Surg. 2017;46(4):496-502.. On the other hand, a preclinical study demonstrated that there was no deleterious effect of nicotine on the osseointegration process. However, the administration of this medication began just after implant placement, and this study design limits the applicability of these findings since patients will not suddenly initiate smoking habits after the surgical procedure if they do not have this habit before the intervention¹⁸18. Linden, MSS; Bittencourt, ME; Carli, JP; Miyagaki, DC; Santos, PLD; Paranhos, LR; et al. The effects of subcutaneous injection of nicotine on osseointegration of machined and anodized implants in rabbits. Acta Cir Bras. 2018;33(1):31-9..

Another important finding in this study was the reversed of the harmful effects of nicotine, especially at the longest experimental period (45 days), provided by the superhydrophilic surfaces. This good outcome of superhydrophilic surfaces is related to their high degree of wettability, which increases adhesion, differentiation, and osteoblastic activity¹⁹19. Calciolari, E; Hamlet, S; Ivanovski, S; Donos, N. Pro-osteogenic properties of hydrophilic and hydrophobic titanium surfaces: Crosstalk between signalling pathways in in vivo models. J Periodontal Res. 2018;53(4):598-609.. Indeed, preclinical studies have shown that superhydrophilic surfaces improve osseointegration in native¹³13. Buser, D; Broggini, N; Wieland, M; Schenk, RK; Denzer ,AJ; Cochran, DL; et al. Enhanced bone apposition to a chemically modified SLA titanium surface. J Dent Res. 2004;83(7):529-33. and grafted bone¹²12. Pinotti, FE; de Oliveira, G; Aroni, MAT; Marcantonio RAC; Marcantonio, E Jr;. Analysis of osseointegration of implants with hydrophilic surfaces in grafted areas: A Preclinical study. Clin Oral Implants Res. 2018;29(10):963-72.. Superhydrophilic surfaces improved the osseointegration of implants placed in rabbit tibiae 28 days after the surgical procedure compared with a control surface¹⁵15. Sartoretto, SC; Alves, AT; Resende, RF; Calasans-Maia ,J; Granjeiro, JM; Calasans-Maia, MD. Early osseointegration driven by the surface chemistry and wettability of dental implants. J Appl Oral Sci. 2015;23(3):279-87., improved the osseointegration of the tibiae of rats grafted with osteoconductive bone substitutes 15 and 45 days after implant placement¹²12. Pinotti, FE; de Oliveira, G; Aroni, MAT; Marcantonio RAC; Marcantonio, E Jr;. Analysis of osseointegration of implants with hydrophilic surfaces in grafted areas: A Preclinical study. Clin Oral Implants Res. 2018;29(10):963-72., and improved the osseointegration 90 days after implant placement in diabetic pig calvaria compared with control surfaces²⁰20. Schlegel, KA; Prechtl, C; Most, T; Seidl, C; Lutz, R; von Wilmowsky, C. Osseointegration of SLActive implants in diabetic pigs. Clin Oral Implants Res. 2013;24(2):128-34.. In healthy humans, an improvement in the osseointegration process has also been demonstrated in implants with superhydrophilic surfaces compared to implants with control surfaces after 2-4 weeks of implant placement¹⁴14. Lang, NP; Salvi, GE; Huynh-Ba, G; Ivanovski, S; Donos ,N; Bosshardt, DD. Early osseointegration to hydrophilic and hydrophobic implant surfaces in humans. Clin Oral Implants Res. 2011;22(4):349-56..

Despite the improvement in the %BIC and %BBT at the 45-days periods, the removal torque was lower in nicotine rats in this same period. Since the bone formation occurred in slow rats in the nicotine animals²¹21. Schroter, S; Freude, T; Kopp, MM; Konstantinidis, L; Dobele, S; Stockle, U; et al. Smoking and unstable hinge fractures cause delayed gap filling irrespective of early weight bearing after open wedge osteotomy. Arthroscopy. 2015;31(2):254-65., it is possible that the bone around the implants observed at the 45-days was more immature in nicotine than in control animals and this may be the reason for the lower biomechanical entanglement observed in the nicotine animals. All these findings suggest that the immediate and early load in dental implants with superhydrophilic surfaces placed in smokers must be avoid.

An important fact is that the systemic changes induced by nicotine can influence the host immunoinflammatory response for a long-term and the implants placed in smoking patients have lower success and survival rates than in non-smoking patients⁶6. Costa, FO; Lages, EJP; Cortelli, SC; Cortelli, JR; Mattos-Pereira, GH; Lima, RPE; et al. Association between cumulative smoking exposure, span since smoking cessation, and peri-implantitis: a cross-sectional study. Clin Oral Investig. 2022.. This host response alteration observed in smokers increases their susceptibility to presents a more prevalent and severe periodontitis and periimplantitis⁴4. Javed, F; Rahman, I; Romanos, GE. Tobacco-product usage as a risk factor for dental implants. Periodontol 2000. 2019;81(1):48-56.. Although this aspect has not been tested in this study, it is possible that the superhydrophilic surface will increase resistance to the establishment and progression of peri-implant disease. This hypothesis must be tested in future studies.

The quest to improve the osseointegration process in smoking patients can not only start with interventions to improve the surfaces of the implants but also with approaches to induce the patient to quit smoking to benefit the osseointegration process⁶6. Costa, FO; Lages, EJP; Cortelli, SC; Cortelli, JR; Mattos-Pereira, GH; Lima, RPE; et al. Association between cumulative smoking exposure, span since smoking cessation, and peri-implantitis: a cross-sectional study. Clin Oral Investig. 2022.. A preclinical study showed that when rats that inhaled cigarette smoke received implants in their tibia, the cessation of this inhalation during the healing period was sufficient to improve the osseointegration process²²22. Cesar-Neto, JB; Benatt,i BB; Sallum, EA; Sallum, AW; Nociti, FH Jr; Bone filling around titanium implants may benefit from smoking cessation: a histologic study in rats. J Periodontol. 2005;76(9):1476-81.. Other clinical studies have shown that quitting smoking benefits the treatment of periodontal disease and improves periodontal parameters in these populations²³23. SSY, AL; Natto, ZS; Middle, JB; Gyurko, R; O'Neill, R; Steffensen, B. Association between time since quitting smoking and periodontitis in former smokers in the National Health and Nutrition Examination Surveys (NHANES) 2009 to 2012. J Periodontol. 2019;90(1):16-25.. However, the effect of quitting smoking on osseointegration in humans lacks further information and confirmation.

This study has as a limitation in that only nicotine was used to disrupt the osseointegration process to mimic the condition of active smokers. However, several other toxic substances can be formed during smoking, and the effect of all of these associated substances can be even more harmful to the osseointegration process that was demonstrated in this study. Other experimental models that mimic the smoking habit simulate the inhalation of smoke²⁴24. Pavone, C; Scardueli, CR; de Oliveira, G; Cerri, PS; Marcantonio Junior, E; Marcantonio, RAC. Effects of an Er,Cr:YSGG Laser on Bone Regeneration in Critical-Sized Calvarial Defects of Rats Exposed to Inhalation of Cigarette Smoke. Photobiomodul Photomed Laser Surg. 2019;37(8):500-7., which also has limitations in mimicking a passive smoker condition Despite these limitations, the model used mimics the systemic effects caused by smoking in the osseointegration process, as demonstrated in a previous systematic literature review¹¹11. Ghanem, A; Abduljabbar, T; Akram, Z; Vohra, F; Kellesarian ,SV; Javed, F. A systematic review and meta-analysis of pre-clinical studies assessing the effect of nicotine on osseointegration. Int J Oral Maxillofac Surg. 2017;46(4):496-502.. Furthermore, the parameters tested in this pre-clinical study provides limited information about the clinical outcomes regarding the osseointegration of dental implants, and the hypothesis that the superhydrophilic implants surfaces improve the osseointegration in smokers must the tests in future clinical studies.

Conclusion

The nicotine administration reduces the osseointegration at 15 days. The superhydrophilic surface equalized the osseointegration in nicotine-exposed animals compared with healthy animals after 45 days of implant placement.

Acknowledgments

This study received a financial support by the brazilian agency FAPESP( Fundação de Amparo a Pesquisa do Estado de São Paulo - 2018/01610-0)

References

¹
Galindo-Moreno, P; Nilsson, P; King, P; Worsaae, N; Schramm, A; Padial-Molina, M; et al. Clinical and radiographic evaluation of early loaded narrow-diameter implants: 5-year follow-up of a multicenter prospective clinical study. Clin Oral Implants Res. 2017;28(12):1584-91.
²
Khandelwal, N; Oates, TW; Vargas, A; Alexander, PP; Schoolfield, JD; Alex McMahan, C. Conventional SLA and chemically modified SLA implants in patients with poorly controlled type 2 diabetes mellitus--a randomized controlled trial. Clin Oral Implants Res. 2013;24(1):13-9.
³
Helal ,O; Gostemeyer, G; Krois, J; Fawzy, El; Sayed, K; Graetz, C; Schwendicke, F. Predictors for tooth loss in periodontitis patients: Systematic review and meta-analysis. J Clin Periodontol. 2019;46(7):699-712.
⁴
Javed, F; Rahman, I; Romanos, GE. Tobacco-product usage as a risk factor for dental implants. Periodontol 2000. 2019;81(1):48-56.
⁵
Windael, S; Vervaeke, S; De Buyser, S; De Bruyn, H; Collaert, B. The Long-Term Effect of Smoking on 10 Years' Survival and Success of Dental Implants: A Prospective Analysis of 453 Implants in a Non-University Setting. J Clin Med. 2020;9(4).
⁶
Costa, FO; Lages, EJP; Cortelli, SC; Cortelli, JR; Mattos-Pereira, GH; Lima, RPE; et al. Association between cumulative smoking exposure, span since smoking cessation, and peri-implantitis: a cross-sectional study. Clin Oral Investig. 2022.
⁷
Davies, CS; Ismail, A. Nicotine has deleterious effects on wound healing through increased vasoconstriction. BMJ. 2016;353:i2709.
⁸
Fowler, CD; Turner, JR; Imad Damaj, M. Molecular Mechanisms Associated with Nicotine Pharmacology and Dependence. Handb Exp Pharmacol. 2020;258:373-93.
⁹
Ma, L; Zheng, LW; Sham, MH; Cheung, LK. Uncoupled angiogenesis and osteogenesis in nicotine-compromised bone healing. J Bone Miner Res. 2010;25(6):1305-13.
¹⁰
Wong, LS; Green, HM; Feugate, JE; Yadav, M; Nothnagel, EA; Martins-Green, M. Effects of "second-hand" smoke on structure and function of fibroblasts, cells that are critical for tissue repair and remodeling. BMC Cell Biol. 2004;5:13.
¹¹
Ghanem, A; Abduljabbar, T; Akram, Z; Vohra, F; Kellesarian ,SV; Javed, F. A systematic review and meta-analysis of pre-clinical studies assessing the effect of nicotine on osseointegration. Int J Oral Maxillofac Surg. 2017;46(4):496-502.
¹²
Pinotti, FE; de Oliveira, G; Aroni, MAT; Marcantonio RAC; Marcantonio, E Jr;. Analysis of osseointegration of implants with hydrophilic surfaces in grafted areas: A Preclinical study. Clin Oral Implants Res. 2018;29(10):963-72.
¹³
Buser, D; Broggini, N; Wieland, M; Schenk, RK; Denzer ,AJ; Cochran, DL; et al. Enhanced bone apposition to a chemically modified SLA titanium surface. J Dent Res. 2004;83(7):529-33.
¹⁴
Lang, NP; Salvi, GE; Huynh-Ba, G; Ivanovski, S; Donos ,N; Bosshardt, DD. Early osseointegration to hydrophilic and hydrophobic implant surfaces in humans. Clin Oral Implants Res. 2011;22(4):349-56.
¹⁵
Sartoretto, SC; Alves, AT; Resende, RF; Calasans-Maia ,J; Granjeiro, JM; Calasans-Maia, MD. Early osseointegration driven by the surface chemistry and wettability of dental implants. J Appl Oral Sci. 2015;23(3):279-87.
¹⁶
de Almeida, JM; de Moraes, RO; Gusman, DJ; Faleiros, PL; Nagata, MJ; Garcia, VG; et al. Influence of low-level laser therapy on the healing process of autogenous bone block grafts in the jaws of systemically nicotine-modified rats: A histomorphometric study. Arch Oral Biol. 2017;75:21-30.
¹⁷
Hernigou, J; Schuind, F. Tobacco and bone fractures: A review of the facts and issues that every orthopaedic surgeon should know. Bone Joint Res. 2019;8(6):255-65.
¹⁸
Linden, MSS; Bittencourt, ME; Carli, JP; Miyagaki, DC; Santos, PLD; Paranhos, LR; et al. The effects of subcutaneous injection of nicotine on osseointegration of machined and anodized implants in rabbits. Acta Cir Bras. 2018;33(1):31-9.
¹⁹
Calciolari, E; Hamlet, S; Ivanovski, S; Donos, N. Pro-osteogenic properties of hydrophilic and hydrophobic titanium surfaces: Crosstalk between signalling pathways in in vivo models. J Periodontal Res. 2018;53(4):598-609.
²⁰
Schlegel, KA; Prechtl, C; Most, T; Seidl, C; Lutz, R; von Wilmowsky, C. Osseointegration of SLActive implants in diabetic pigs. Clin Oral Implants Res. 2013;24(2):128-34.
²¹
Schroter, S; Freude, T; Kopp, MM; Konstantinidis, L; Dobele, S; Stockle, U; et al. Smoking and unstable hinge fractures cause delayed gap filling irrespective of early weight bearing after open wedge osteotomy. Arthroscopy. 2015;31(2):254-65.
²²
Cesar-Neto, JB; Benatt,i BB; Sallum, EA; Sallum, AW; Nociti, FH Jr; Bone filling around titanium implants may benefit from smoking cessation: a histologic study in rats. J Periodontol. 2005;76(9):1476-81.
²³
SSY, AL; Natto, ZS; Middle, JB; Gyurko, R; O'Neill, R; Steffensen, B. Association between time since quitting smoking and periodontitis in former smokers in the National Health and Nutrition Examination Surveys (NHANES) 2009 to 2012. J Periodontol. 2019;90(1):16-25.
²⁴
Pavone, C; Scardueli, CR; de Oliveira, G; Cerri, PS; Marcantonio Junior, E; Marcantonio, RAC. Effects of an Er,Cr:YSGG Laser on Bone Regeneration in Critical-Sized Calvarial Defects of Rats Exposed to Inhalation of Cigarette Smoke. Photobiomodul Photomed Laser Surg. 2019;37(8):500-7.

Data availability statement

The data of this study will be available at the repository of the São Paulo State University (Unesp), School of Dentistry, Araraquara since thesis a part of the pHD thesis of Dr. Felipe Eduardo Pinotti; Funding statement This study was financial by the brazilian agency FAPESP (Fundação de Amparo a pesquisa do Estado de São Paulo - 2018/01610-0).

Publication Dates

Publication in this collection
15 May 2023
Date of issue
Mar-Apr 2023

History

Received
15 June 2022
Accepted
15 Feb 2023

This is an open-access article distributed under the terms of the Creative Commons Attribution License

[1] ¹
Galindo-Moreno, P; Nilsson, P; King, P; Worsaae, N; Schramm, A; Padial-Molina, M; et al. Clinical and radiographic evaluation of early loaded narrow-diameter implants: 5-year follow-up of a multicenter prospective clinical study. Clin Oral Implants Res. 2017;28(12):1584-91.

[2] ²
Khandelwal, N; Oates, TW; Vargas, A; Alexander, PP; Schoolfield, JD; Alex McMahan, C. Conventional SLA and chemically modified SLA implants in patients with poorly controlled type 2 diabetes mellitus--a randomized controlled trial. Clin Oral Implants Res. 2013;24(1):13-9.

[3] ³
Helal ,O; Gostemeyer, G; Krois, J; Fawzy, El; Sayed, K; Graetz, C; Schwendicke, F. Predictors for tooth loss in periodontitis patients: Systematic review and meta-analysis. J Clin Periodontol. 2019;46(7):699-712.

[4] ⁴
Javed, F; Rahman, I; Romanos, GE. Tobacco-product usage as a risk factor for dental implants. Periodontol 2000. 2019;81(1):48-56.

[5] ⁵
Windael, S; Vervaeke, S; De Buyser, S; De Bruyn, H; Collaert, B. The Long-Term Effect of Smoking on 10 Years' Survival and Success of Dental Implants: A Prospective Analysis of 453 Implants in a Non-University Setting. J Clin Med. 2020;9(4).

[6] ⁶
Costa, FO; Lages, EJP; Cortelli, SC; Cortelli, JR; Mattos-Pereira, GH; Lima, RPE; et al. Association between cumulative smoking exposure, span since smoking cessation, and peri-implantitis: a cross-sectional study. Clin Oral Investig. 2022.

[7] ⁷
Davies, CS; Ismail, A. Nicotine has deleterious effects on wound healing through increased vasoconstriction. BMJ. 2016;353:i2709.

[8] ⁸
Fowler, CD; Turner, JR; Imad Damaj, M. Molecular Mechanisms Associated with Nicotine Pharmacology and Dependence. Handb Exp Pharmacol. 2020;258:373-93.

[9] ⁹
Ma, L; Zheng, LW; Sham, MH; Cheung, LK. Uncoupled angiogenesis and osteogenesis in nicotine-compromised bone healing. J Bone Miner Res. 2010;25(6):1305-13.

[10] ¹⁰
Wong, LS; Green, HM; Feugate, JE; Yadav, M; Nothnagel, EA; Martins-Green, M. Effects of "second-hand" smoke on structure and function of fibroblasts, cells that are critical for tissue repair and remodeling. BMC Cell Biol. 2004;5:13.

[11] ¹¹
Ghanem, A; Abduljabbar, T; Akram, Z; Vohra, F; Kellesarian ,SV; Javed, F. A systematic review and meta-analysis of pre-clinical studies assessing the effect of nicotine on osseointegration. Int J Oral Maxillofac Surg. 2017;46(4):496-502.

[12] ¹²
Pinotti, FE; de Oliveira, G; Aroni, MAT; Marcantonio RAC; Marcantonio, E Jr;. Analysis of osseointegration of implants with hydrophilic surfaces in grafted areas: A Preclinical study. Clin Oral Implants Res. 2018;29(10):963-72.

[13] ¹³
Buser, D; Broggini, N; Wieland, M; Schenk, RK; Denzer ,AJ; Cochran, DL; et al. Enhanced bone apposition to a chemically modified SLA titanium surface. J Dent Res. 2004;83(7):529-33.

[14] ¹⁴
Lang, NP; Salvi, GE; Huynh-Ba, G; Ivanovski, S; Donos ,N; Bosshardt, DD. Early osseointegration to hydrophilic and hydrophobic implant surfaces in humans. Clin Oral Implants Res. 2011;22(4):349-56.

[15] ¹⁵
Sartoretto, SC; Alves, AT; Resende, RF; Calasans-Maia ,J; Granjeiro, JM; Calasans-Maia, MD. Early osseointegration driven by the surface chemistry and wettability of dental implants. J Appl Oral Sci. 2015;23(3):279-87.

[16] ¹⁶
de Almeida, JM; de Moraes, RO; Gusman, DJ; Faleiros, PL; Nagata, MJ; Garcia, VG; et al. Influence of low-level laser therapy on the healing process of autogenous bone block grafts in the jaws of systemically nicotine-modified rats: A histomorphometric study. Arch Oral Biol. 2017;75:21-30.

[17] ¹⁷
Hernigou, J; Schuind, F. Tobacco and bone fractures: A review of the facts and issues that every orthopaedic surgeon should know. Bone Joint Res. 2019;8(6):255-65.

[18] ¹⁸
Linden, MSS; Bittencourt, ME; Carli, JP; Miyagaki, DC; Santos, PLD; Paranhos, LR; et al. The effects of subcutaneous injection of nicotine on osseointegration of machined and anodized implants in rabbits. Acta Cir Bras. 2018;33(1):31-9.

[19] ¹⁹
Calciolari, E; Hamlet, S; Ivanovski, S; Donos, N. Pro-osteogenic properties of hydrophilic and hydrophobic titanium surfaces: Crosstalk between signalling pathways in in vivo models. J Periodontal Res. 2018;53(4):598-609.

[20] ²⁰
Schlegel, KA; Prechtl, C; Most, T; Seidl, C; Lutz, R; von Wilmowsky, C. Osseointegration of SLActive implants in diabetic pigs. Clin Oral Implants Res. 2013;24(2):128-34.

[21] ²¹
Schroter, S; Freude, T; Kopp, MM; Konstantinidis, L; Dobele, S; Stockle, U; et al. Smoking and unstable hinge fractures cause delayed gap filling irrespective of early weight bearing after open wedge osteotomy. Arthroscopy. 2015;31(2):254-65.

[22] ²²
Cesar-Neto, JB; Benatt,i BB; Sallum, EA; Sallum, AW; Nociti, FH Jr; Bone filling around titanium implants may benefit from smoking cessation: a histologic study in rats. J Periodontol. 2005;76(9):1476-81.

[23] ²³
SSY, AL; Natto, ZS; Middle, JB; Gyurko, R; O'Neill, R; Steffensen, B. Association between time since quitting smoking and periodontitis in former smokers in the National Health and Nutrition Examination Surveys (NHANES) 2009 to 2012. J Periodontol. 2019;90(1):16-25.

[24] ²⁴
Pavone, C; Scardueli, CR; de Oliveira, G; Cerri, PS; Marcantonio Junior, E; Marcantonio, RAC. Effects of an Er,Cr:YSGG Laser on Bone Regeneration in Critical-Sized Calvarial Defects of Rats Exposed to Inhalation of Cigarette Smoke. Photobiomodul Photomed Laser Surg. 2019;37(8):500-7.

Brasil

Brasil

Osseointegration of implants with superhydrophilic surfaces in rats with high serum levels of nicotine

Abstract

Resumo

Introduction

Materials and methods

Study design and ethical considerations

Surgical Procedure

Biomechanical analysis

Microtomographic analysis

Histomorphometric analysis

Sample size calculation

Statistical analysis

Results

Biomechanical analysis

Microcomputed tomographic analysis

Histomorphometric analysis

Discussion

Conclusion

Acknowledgments

References

Data availability statement

Publication Dates

History