The Science Behind Bioactive Dental Adhesive Systems: Benefits and Applications

Abstract

The integration of bioactive dental adhesive systems represents a significant advancement in restorative dentistry, offering enhanced therapeutic benefits beyond traditional adhesive materials. This review explores the underlying science, benefits, and clinical applications of bioactive dental adhesives. Bioactive adhesives are designed to interact favorably with biological tissues, promoting remineralization, reducing bacterial colonization, and improving the longevity of dental restorations. These adhesives incorporate various bioactive compounds, such as calcium phosphate, fluoride, and antimicrobial agents, which contribute to the regeneration of dentin and the prevention of secondary caries. The application of bioactive dental adhesives spans a wide range of restorative procedures, including direct and indirect restorations, sealants, and cavity liners. Clinical studies have demonstrated improved outcomes in terms of bond strength, durability, and patient satisfaction. By leveraging the bioactive properties of these advanced materials, dental practitioners can provide more effective and sustainable treatments, ultimately leading to better oral health and patient care. This review underscores the potential of bioactive dental adhesive systems to revolutionize dental practice and highlights the need for further research to optimize their formulations and applications.

Keywords:

Bioactive dental adhesives, Restorative dentistry, Remineralization, Dental materials, Dental restorations

References

Brkanović S, Sever EK, Vukelja J, Ivica A, Miletić I, Krmek SJ. Comparison of Different Universal Adhesive Systems on Dentin Bond Strength. Materials. 2023 Feb 12;16(4):1530.

Cardoso, M.V.; de Almeida Neves, A.; Mine, A.; Coutinho, E.; Van Landuyt, K.; De Munck, J.; Van Meerbeek, B. Current aspects on bonding effectiveness and stability in adhesive dentistry. Aust. Dent. J. 2011, 56, 31–44.

Kaisarly, D.; El Gezawi, M. Polymerization shrinkage assessment of dental resin composites: A literature review. Odontology 2016, 104, 257–270.

Yamauchi, K.; Tsujimoto, A.; Jurado, C.A.; Shimatani, Y.; Nagura, Y.; Takamiza-wa, T.; Barkmeier, W.W.; Latta, M.A.; Miyazaki, M. Etch-and-rinse vs self-etch mode for dentin bonding effectiveness of universal adhesives. J. Oral Sci. 2019, 61, 549–553.

Jang, J.H.; Lee, M.G.; Woo, S.U.; Lee, C.O.; Yi, J.K.; Kim, D.S. Comparative study of the dentin bond strength of a new universal adhesive. Dent. Mater. J. 2016, 35, 606–612.

Tsujimoto, A.; Barkmeier, W.W.; Takamizawa, T.; Watanabe, H.; Johnson, W.W.; Latta, M.A.; Miyazaki, M. Simulated localized wear of resin luting cement for universal adhesive systems with different curing mode. J. Oral Sci. 2018, 60, 29–36.

Tsujimoto, A.; Barkmeier, W.W.; Takamizawa, T.; Wilwerding, T.; Latta, M.A.; Miyazaki, M. Interfacial characteristics and bond durability on universal adhesives to various substrates. Oper Dent. 2017, 42, e59–e70.

Nagura, Y.; Tsujimoto, A.; Fisher, N.G.; Baruth, A.G.; Barkmeier, W.W.; Takamizawa, T. The effect of reduced application time of universal adhesives on enamel bond fatigue durability and surface morphology. Oper Dent. 2019, 4, 42–53.

Salehi A, Sadeghi M, Salehi N. The Effect of Carbamide Peroxide Bleaching Gel with and without Remineralizing Agents on Microtensile Bond Strength of Resin Composites to Enamel. International Journal of Medical Science and Dental Health. 2024 Jun 30;10(06):107-16.

Sano, H.; Takatsu, T.; Ciucchi, B.; Horner, J.A.; Matthews, W.G.; Pashley, D.H. Nanoleakage: Leakage within the hybrid layer. Oper. Dent. 1995, 20, 18–25.

Salehi A, Sadeghi M, Salehi N, Roberts M. The Effect of Carbamide Peroxide Bleaching Gel Containing Remineralization Agents on the Bond Strength of Universal Adhesives to Enamel. Available at SSRN 4817857. 2024 May 5.

Irmak, Ö.; Yaman, B.C.; Orhan, E.O.; Ozer, F.; Blatz, M.B. Effect of rubbing force magnitude on bond strength of universal adhesives applied in self-etch mode. Dent. Mater. J. 2018, 37, 139–145.

Al-Qarni FD. Development of Novel Therapeutic Dental Adhesives to Inhibit Secondary Caries (Doctoral dissertation, University of Maryland, Baltimore). 2018.

Ferrando-Magraner, E.; Bellot-Arcís, C.; Paredes-Gallardo, V.; Almerich-Silla, J.M.; García-Sanz, V.; Fernández-Alonso, M. Antibacterial properties of nanoparticles in dental restorative materials. A systematic review and meta-analysis. Medicina 2020, 56, 55.

Lung, C.Y.K.; Sarfraz, Z.; Habib, A.; Khan, A.S.; Matinlinna, J.P. Effect of silanization of hydroxyapatite fillers on physical and mechanical properties of a bis-GMA based resin composite. J. Mech. Behav. Biomed. Mater. 2016, 54, 283–294.

Hussain, N.; Khalid, H.; AlMaimouni, Y.K.; Ikram, S.; Khan, M.; Din, S.U.; Talal, A.; Khan, A.S. Microwave assisted urethane grafted nano-apatites for dental adhesives. J. Bioact. Compat. Polym. 2020, 35, 479–490.

Dias, P.G.; Da Silva, E.M.; Carvalho, C.; Miranda, M.; Portela, M.B.; Amaral, C.M. Characterization and Antibacterial Effect of an Experimental Adhesive Containing Different Concentrations of Proanthocyanidin. J. Adhes. Dent. 2020, 22, 139–147.

Garcia, I.M.; Souza, V.S.; Scholten, J.D.; Collares, F.M. Quantum Dots of Tantalum Oxide with an Imidazolium Ionic Liquid as Antibacterial Agent for Adhesive Resin. J. Adhes. Dent. 2020, 22, 207–214.

Fujimura, Y.; Weerasinghe, D.; Kawashima, M. Development of an antibacterial bioactive dental adhesive: Simplicity and innovation. Am. J. Dent. 2018, 31, 13B–16B.

Cruzetta, L.; Garcia, I.M.; de Souza Balbinot, G.; Motta, A.S.; Collares, F.M.; Sauro, S.; CB Leitune, V. Evaluation of the Physicochemical and Antibacterial Properties of Experimental Adhesives Doped with Lithium Niobate. Polymers 2020, 12, 1330.

Dawes C. What is the critical pH and why does a tooth dissolve in acid? J. Can. Dent. Assoc. 2003; 69:722–724.

Tay F.R., Pashley D.H., Yiu C., Cheong C., Hashimoto M., Itou K., Yoshiyama M., King N.M. Nanoleakage types and potential implications: Evidence from unfilled and filled adhesives with the same resin composition. Am. J. Dent. 2004; 17:182–190.

Breschi L., Mazzoni A., Ruggeri A., Cadenaro M., di Lenarda R., de Stefano Dorigo E. Dental adhesion review: Aging and stability of the bonded interface. Dent. Mater. 2008; 24:90–101.

Guedes A.P., Moda M.D., Suzuki T.Y., Godas A.G., Sundfeld R.H., Briso A.L., Santos P.H. Effect of Fluoride-Releasing Adhesive Systems on the Mechanical Properties of Eroded Dentin. Braz. Dent. J. 2016; 27:153–159.

Chen L., Shen H., Suh B.I. Bioactive dental restorative materials: A review. Am. J. Dent. 2013; 26:219–227.

Comba A., Maravic T., Valente L., Girlando M., Cunha S.R., Checchi V., Salgarello S., Tay F.R., Scotti N., Breschi L., et al. Effect of benzalkonium chloride on dentin bond strength and endogenous enzymatic activity. J. Dent. 2019; 85:25–32.

Maravic T., Comba A., Cunha S.R., Angeloni V., Cadenaro M., Visinitini E., Navarra C.O., Salgarello S., Breschi L., Mazzoni A. Long-term bond strength and endogenous enzymatic activity of a chlorhexidine-containing commercially available adhesive. J. Dent. 2019; 84:60–66.

Kim HJ, Jang JH, Woo SU, Choi KK, Kim SY, Ferracane JL, Lee JH, Choi D, Choi S, Kim S, Bang A. Effect of novel bioactive glass-containing dentin adhesive on the permeability of demineralized dentin. Materials. 2021 Sep 19;14(18):5423.

Pashley D.H., Carvalho R. Dentine permeability and dentine adhesion. J. Dent. 1997; 25:355–372.

Rosales-Leal J.I., de la Torre-Moreno F.J., Bravo M. Effect of pulp pressure on the micropermeability and sealing ability of etch & rinse and self-etching adhesives. Oper. Dent. 2007;32: 242–250.

Farooq I, Ali S, Al-Saleh S, AlHamdan EM, AlRefeai MH, Abduljabbar T, Vohra F. Synergistic effect of bioactive inorganic fillers in enhancing properties of dentin adhesives—A review. Polymers. 2021 Jun 30;13(13):2169.

Gajewski V.E., Pfeifer C.S., Froes-Salgado N.R., Boaro L.C., Braga R.R. Monomers used in resin composites: Degree of conversion, mechanical properties and water sorption/solubility. Braz. Dent. J. 2012;23:508–514.

Iafisco M., Degli Esposti L., Ramirez-Rodriguez G.B., Carella F., Gomez-Morales J., Ionescu A.C., Brambilla E., Tampieri A., Delgado-Lopez J.M. Fluoride-doped amorphous calcium phosphate nanoparticles as a promising biomimetic material for dental remineralization. Sci. Rep. 2018;8:17016.

Kulshrestha S., Khan S., Hasan S., Khan M.E., Misba L., Khan A.U. Calcium fluoride nanoparticles induced suppression of Streptococcus mutans biofilm: An in vitro and in vivo approach. Appl. Microbiol. Biotechnol. 2016;100:1901–1914.

Cheng L., Weir M.D., Xu H.H., Kraigsley A.M., Lin N.J., Lin-Gibson S., Zhou X. Antibacterial and physical properties of calcium-phosphate and calcium-fluoride nanocomposites with chlorhexidine. Dent. Mater. 2012;28:573–583.

Al-Harbi N., Mohammed H., Al-Hadeethi Y., Bakry A.S., Umar A., Hussein M.A., Abbassy M.A., Vaidya K.G., Berakdar G.A., Mkawi E.M., et al. Silica-Based Bioactive Glasses and Their Applications in Hard Tissue Regeneration: A Review. Pharmaceuticals. 2021;14:75.

Baig M.S., Fleming G.J. Conventional glass-ionomer materials: A review of the developments in glass powder, polyacid liquid and the strategies of reinforcement. J. Dent. 2015;43:897–912.

Melo M.A., Cheng L., Zhang K., Weir M.D., Rodrigues L.K., Xu H.H. Novel dental adhesives containing nanoparticles of silver and amorphous calcium phosphate. Dent. Mater. 2013;29:199–210.

Zhao J., Liu Y., Sun W.B., Zhang H. Amorphous calcium phosphate and its application in dentistry. Chem. Cent. J. 2011;5:40.

Meyer F, Zur Wiesche ES, Amaechi BT, Limeback H, Enax J. Caries etiology and preventive measures. European Journal of Dentistry. 2024 Mar 31.

Welch K, Cai Y, Engqvist H, Strømme M. Dental adhesives with bioactive and on-demand bactericidal properties. Dental Materials. 2010 May 1;26(5):491-9.

Sauro, S.; Osorio, R.; Osorio, E.; Watson, T.F.; Toledano, M. Novel light-curable materials containing experimental bioactive micro-fillers remineralise mineral-depleted bonded-dentine interfaces. J. Biomater. Sci. Polym. Ed. 2013, 24, 940–956.

Scribante A, Farahani MR, Marino G, Matera C, y Baena RR, Lanteri V, Butera A. Biomimetic effect of nano-hydroxyapatite in demineralized enamel before orthodontic bonding of brackets and attachments: visual, adhesion strength, and hardness in in vitro tests. BioMed Research International. 2020;2020.

Liu XX, Tenenbaum HC, Wilder RS, Quock R, Hewlett ER, Ren YF. Pathogenesis, diagnosis and management of dentin hypersensitivity: an evidence-based overview for dental practitioners. BMC oral health. 2020 Dec;20:1-0.

Profeta, A.C.; Mannocci, F.; Foxton, R.; Watson, T.F.; Feitosa, V.P.; De Carlo, B.; Mongiorgi, R.; Valdre, G.; Sauro, S. Experimental etch-and-rinse adhesives doped with bioactive calcium silicate-based micro-fillers to generate therapeutic resin-dentin interfaces. Dent. Mater. 2013, 29, 729–741.

Tiskaya, M.; Shahid, S.; Gillam, D.; Hill, R. The use of bioactive glass (BAG) in dental composites: A critical review. Dent. Mater. 2021, 37, 296–310.

Delaviz Y, Finer Y, Santerre JP. Biodegradation of resin composites and adhesives by oral bacteria and saliva: a rationale for new material designs that consider the clinical environment and treatment challenges. Dental Materials. 2014 Jan 1;30(1):16-32.

Fujimura Y, Weerasinghe DI, Kawashima MI. Development of an antibacterial bioactive dental adhesive: Simplicity and innovation. Am. J. Dent. 2018 Nov 15;31:13B-6B.

Xie X, Wang L, Xing D, Zhang K, Weir MD, Liu H, Bai Y, Xu HH. Novel dental adhesive with triple benefits of calcium phosphate recharge, protein-repellent and antibacterial functions. Dental Materials. 2017 May 1;33(5):553-63.

Zhou W, Chen H, Weir MD, Oates TW, Zhou X, Wang S, Cheng L, Xu HH. Novel bioactive dental restorations to inhibit secondary caries in enamel and dentin under oral biofilms. Journal of Dentistry. 2023 Apr 1:104497.

Tebyaniyan H, Hussain A, Vivian M. Current antibacterial agents in dental bonding systems: a comprehensive overview. Future Microbiology. 2023 Aug;18(12):825-44.

Tjäderhane L, Tezvergil-Mutluay A. Performance of adhesives and restorative materials after selective removal of carious lesions: restorative materials with anticaries properties. Dental Clinics. 2019 Oct 1;63(4):715-29.

Blum IR, Özcan M. Reparative dentistry: possibilities and limitations. Current oral health reports. 2018 Dec;5:264-9.

Khan AS, Syed MR. A review of bioceramics-based dental restorative materials. Dental Materials Journal. 2019 Mar 28;38(2):163-76.

Zhou W, Liu S, Zhou X, Hannig M, Rupf S, Feng J, Peng X, Cheng L. Modifying adhesive materials to improve the longevity of resinous restorations. International journal of molecular sciences. 2019 Feb 8;20(3):723.

Li Q, Huang G, Li A, Qiu D, Dong Y. Promoting Bond Durability by a Novel Fabricated Bioactive Dentin Adhesive. Journal of Dentistry. 2024 Feb 28:104905.

Vasiliu S, Racovita S, Gugoasa IA, Lungan MA, Popa M, Desbrieres J. The benefits of smart nanoparticles in dental applications. International journal of molecular sciences. 2021 Mar 4;22(5):2585.

Zhang L, Weir MD, Hack G, Fouad AF, Xu HH. Rechargeable dental adhesive with calcium phosphate nanoparticles for long-term ion release. Journal of dentistry. 2015 Dec 1;43(12):1587-95.

Kim GE, Leme-Kraus AA, Phansalkar R, Viana G, Wu C, Chen SN, Pauli GF, Bedran-Russo AK. Effect of bioactive primers on bacterial-induced secondary caries at the tooth-resin interface. Operative dentistry. 2017 Mar 1;42(2):196-202.

Neves P, Pires S, Marto CM, Amaro I, Coelho A, Sousa J, Ferreira MM, Botelho MF, Carrilho E, Abrantes AM, Paula AB. Evaluation of Microleakage of a New Bioactive Material for Restoration of Posterior Teeth: An In Vitro Radioactive Model. Applied Sciences. 2022 Nov 21;12(22):11827.

Demirel G, Gür G, Eryılmaz M, Altanlar N. The effects of self-etch bio-active dental adhesive systems on bacterial microleakage. Journal of adhesion science and Technology. 2018 May 19;32(10):1044-54.

Luong MN, Huang L, Chan DC, Sadr A. In vitro study on the effect of a new bioactive desensitizer on dentin tubule sealing and bonding. Journal of Functional Biomaterials. 2020 Jun 2;11(2):38.

Mai S, Zhang Q, Liao M, Ma X, Zhong Y. Recent advances in direct adhesive restoration resin-based dental materials with remineralizing agents. Frontiers in Dental Medicine. 2022 Apr 21;3:868651.

Rattan S, Fawcett D, Tennant M, Granich J, Poinern G. Progress of nanomaterials in preventative and restorative dentistry. Recent Progress in Materials. 2021 Mar;3(1):1-42.

Baraka MM, Ibrahim YM, Helmy RH. ADHESIVE STRATEGIES FOR RESTORING PRIMARY AND YOUNG PERMANENT DENTITION-A REVIEW. Alexandria Dental Journal. 2024 Apr 1;49(1):195-202.

Paulraj J, Maiti S, Shanmugam R. Comparative Analysis of Color Stability and Its Impact on Artificial Aging: An In Vitro Study of Bioactive Chitosan, Titanium, Zirconia, and Hydroxyapatite Nanoparticle-Reinforced Glass Ionomer Cement Compared With Conventional Glass Ionomer Cement. Cureus. 2024 Feb;16(2).

Gavric A, Mirceta D, Jakobovic M, Pavlic A, Zrinski MT, Spalj S. Craniodentofacial characteristics, dental esthetics–related quality of life, and self-esteem. American Journal of Orthodontics and Dentofacial Orthopedics. 2015 Jun 1;147(6):711-8.

Eakle WS, Bastin KG. Dental materials: clinical applications for dental assistants and dental hygienists. Elsevier Health Sciences; 2019 Sep 16.

Zhang OL, Niu JY, Yin IX, Yu OY, Mei ML, Chu CH. Bioactive materials for caries management: A literature review. Dentistry Journal. 2023 Feb 23;11(3):59.

Tjäderhane L. Dentin basic structure, composition, and function. The root canal anatomy in permanent dentition. 2019:17-27.

Miglani S, Aggarwal V, Ahuja B. Dentin hypersensitivity: Recent trends in management. Journal of Conservative Dentistry. 2010 Oct 1;13(4):218-24.

da Cruz LD, de Campos Tuñas IT. Bioactive glass as a treatment option for dentin hypersensitivity. Rev. Bras. Odontol. 2018 Aug 10;75:e1125.

da Rosa WL, Cocco AR, Silva TM, Mesquita LC, Galarca AD, Silva AF, Piva E. C urrent trends and future perspectives of dental pulp capping materials: A systematic review. Journal of Biomedical Materials Research Part B: Applied Biomaterials. 2018 Apr;106(3):1358-68.

Ricucci D, Rôças IN, Alves FR, Cabello PH, Siqueira Jr JF. Outcome of direct pulp capping using calcium hydroxide: a long-term retrospective study. Journal of Endodontics. 2023 Jan 1;49(1):45-54.

Mohamed MH, Refaat WE, Morcos SS. Effect of different fluoride releasing bonding agents in preventing of enamel demineralization around orthodontic brackets. Egyptian Orthodontic Journal. 2016 Dec 1;50(December 2016):13-34.

Melo MA, Morais WA, Passos VF, Lima JP, Rodrigues LK. Fluoride releasing and enamel demineralization around orthodontic brackets by fluoride-releasing composite containing nanoparticles. Clinical oral investigations. 2014 May;18:1343-50.

Tavakolinejad Z, Kamalabadi YM, Salehi A. Comparison of the Shear Bond Strength of Orthodontic Composites Containing Silver and Amorphous Tricalcium Phosphate Nanoparticles: an ex vivo Study. Journal of Dentistry. 2023 Sep;24(3):285.

Wikesjö UM, Selvig KA. Periodontal wound healing and regeneration. Periodontology 2000. 1999 Feb;19(1):21-39.

Fraser D, Caton J, Benoit DS. Periodontal wound healing and regeneration: Insights for engineering new therapeutic approaches. Frontiers in Dental Medicine. 2022 Mar 2;3:815810.

Fagundes TC, Barata TJ, Bresciani E, Santiago SL, Franco EB, Lauris JR, Navarro MF. Seven-year clinical performance of resin composite versus resin-modified glass ionomer restorations in noncarious cervical lesions. Operative Dentistry. 2014 Nov 1;39(6):578-87.

Pameijer CH. A review of luting agents. International journal of dentistry. 2012;2012(1):752861.

Van Meerbeek B, Yoshihara K, Yoshida Y, Mine AJ, De Munck J, Van Landuyt KL. State of the art of self-etch adhesives. Dental materials. 2011 Jan 1;27(1):17-28.

Perdigão J. Current perspectives on dental adhesion:(1) Dentin adhesion–not there yet. Japanese Dental Science Review. 2020 Nov 1;56(1):190-207.

Hanada K, Morotomi T, Washio A, Yada N, Matsuo K, Teshima H, Yokota K, Kitamura C. In vitro and in vivo effects of a novel bioactive glass‐based cement used as a direct pulp capping agent. Journal of Biomedical Materials Research Part B: Applied Biomaterials. 2019 Jan;107(1):161-8.

Camilleri J. The chemical composition of mineral trioxide aggregate. Journal of Conservative Dentistry and Endodontics. 2008 Oct 1;11(4):141-3.

Foxton, R.M., 2020. Current perspectives on dental adhesion:(2) Concepts for operatively managing carious lesions extending into dentine using bioactive and adhesive direct restorative materials. Japanese Dental Science Review, 56(1), pp.208-215.

Nedeljkovic I, Teughels W, De Munck J, Van Meerbeek B, Van Landuyt KL. Is secondary caries with composites a material-based problem?. Dental Materials. 2015 Nov 1;31(11):e247-77.

Baras BH, Melo MA, Thumbigere-Math V, Tay FR, Fouad AF, Oates TW, Weir MD, Cheng L, Xu HH. Novel bioactive and therapeutic root canal sealers with antibacterial and remineralization properties. Materials. 2020 Mar 1;13(5):1096.

Melo MA, Garcia IM, Mokeem L, Weir MD, Xu HH, Montoya C, Orrego S. Developing bioactive dental resins for restorative dentistry. Journal of Dental Research. 2023 Oct;102(11):1180-90.

Crăciunescu EL, Romînu M, Negruţiu ML, Sinescu C, Novac AC, Caplar BD, Pop DM. Indirect Restorative Polymeric Dental Materials.

Verma S, Chaitra TR, Nigam D, Hari R. Biomimetic materials in pediatric dentistry: A review article. GSC Biological and Pharmaceutical Sciences. 2023;23(1):067-75.

Mokeem LS, Garcia IM, Balhaddad AA, Cline K, Rakovsky G, Collares FM, Melo MA. Dental Adhesives: State‐of‐the‐Art, Current Perspectives, and Promising Applications. Adhesives in Biomedical Applications. 2023 Oct 2:253-77.

Acharya S, Raghunath N, Mallikarjun RM, Nalawade T, Gurunathan D, Godhi BS. Bioactive Biosilicate Cements in Pediatric Dentistry–A Review of the Latest Materials. Journal of Pharmacy and Bioallied Sciences. 2024 Apr 1;16(Suppl 2):S1057-63.

Sindhe, S., 2020. Comparison of Coronal Microleakage of MTA-HP, Cem and Biodentine as Intra-Orifice Barriers in Endodontically Treated Teeth-An UV Visible Spectrophotometric Study (Doctoral dissertation, Rajiv Gandhi University of Health Sciences (India)).

Widbiller M, Schmalz G. Endodontic regeneration: Hard shell, soft core. Odontology. 2021 Apr;109(2):303-12.

Zhang N, Melo MA, Chen C, Liu J, Weir MD, Bai Y, Xu HH. Development of a multifunctional adhesive system for prevention of root caries and secondary caries. Dental Materials. 2015 Sep 1;31(9):1119-31.

Ashique S, Hussain A, Khan T, Pal S, Rihan M, Farid A, Webster TJ, Hassan MZ, Asiri YI. Insights into Intra Periodontal Pocket Pathogenesis, Treatment, In Vitro-In Vivo Models, Products and Patents, Challenges and Opportunity. AAPS PharmSciTech. 2024 May 30;25(5):121.

Xu X, He L, Zhu B, Li J, Li J. Advances in polymeric materials for dental applications. Polymer Chemistry. 2017;8(5):807-23.

Al-Dulaijan YA, Balhaddad AA. Prospects on tuning bioactive and antimicrobial denture base resin materials: A narrative review. Polymers. 2022 Dec 23;15(1):54.

Talal A, Nasim HM, Khan AS. Enamel etching and dental adhesives. InAdvanced Dental Biomaterials 2019 Jan 1 (pp. 229-253). Woodhead Publishing.

Talal A, Nasim HM, Khan AS. Enamel etching and dental adhesives. InAdvanced Dental Biomaterials 2019 Jan 1 (pp. 229-253). Woodhead Publishing.

Cocco AR, Maske TT, Lund RG, Moraes RR. The antibacterial and physicochemical properties of a one-step dental adhesive modified with potential antimicrobial agents. International Journal of Adhesion and Adhesives. 2016 Dec 1;71:74-80.

Condò R, Mampieri G, Cioffi A, Cataldi ME, Frustaci I, Giancotti A, et al. Physical and chemical mechanisms involved in adhesion of orthodontic bonding composites: in vitro evaluations. BMC Oral Health. 2021; 21: 1–2.

Sodagar A, Akhoundi MS, Bahador A, Jalali YF, Behzadi Z, Elhaminejad F, et al. Effect of TiO2 nanoparticles incorporation on antibacterial properties and shear bond strength of dental composite used in Orthodontics. Dental Press J Orthod. 2017; 22: 67–74.

Melo MA, Weir MD, Passos VF, Powers M, Xu HH. Phactivated nano-amorphous calcium phosphate-based cement to reduce dental enamel demineralization. Artif Cells Nanomed Biotechnol. 2017; 45: 1778–1785.

Ibrahim MS, Alabbas MA, Alsomaly KU, AlMansour AA, Aljouie AA, Alzahrani MM, Asseri AA, AlHumaid J. Flexural strength, elastic modulus and remineralizing abilities of bioactive resin-based dental sealants. Polymers. 2021 Dec 24;14(1):61.

Ibrahim MS, Garcia IM, Vila T, Balhaddad AA, Collares FM, Weir MD, Xu HH, Melo MA. Multifunctional antibacterial dental sealants suppress biofilms derived from children at high risk of caries. Biomaterials science. 2020;8(12):3472-84.

Pires PM, Neves AD, Makeeva IM, Schwendicke F, Faus-Matoses V, Yoshihara K, Banerjee A, Sauro S. Contemporary restorative ion-releasing materials: Current status, interfacial properties and operative approaches. British Dental Journal. 2020 Oct;229(7):450-8.

Oltramare R, Par M, Mohn D, Wiedemeier DB, Attin T, Tauböck TT. Short-and long-term dentin bond strength of bioactive glass-modified dental adhesives. Nanomaterials. 2021 Jul 23;11(8):1894.

Par M, Gubler A, Attin T, Tarle Z, Tarle A, Prskalo K, Tauböck TT. Effect of adhesive coating on calcium, phosphate, and fluoride release from experimental and commercial remineralizing dental restorative materials. Scientific reports. 2022 Jun 17;12(1):10272.

Örtengren U, Lehrkinder A, Safarloo A, Axelsson J, Lingström P. Opportunities for caries prevention using an ion-releasing coating material: a randomised clinical study. Odontology. 2021 Apr;109:358-67.

Imazato S. Bio-active restorative materials with antibacterial effects: new dimension of innovation in restorative dentistry. Dental materials journal. 2009;28(1):11-9.

Sadeghi M, Salehi A, Roberts MW. Effect of chlorhexidine application on dentin bond strength durability of two etch-and-rinse adhesive versus a universal bond system. Available at SSRN 4817860. 2024 May 5.

Hu X, Sun T, Kuang B, Sun Y, Chen L, Ding H. Bibliometric analysis of dental adhesives: research status and frontier development. Frontiers in Materials. 2023 Oct 31;10:1288717.

Adeola HA. Nanobiotechnology in Regenerative Dental Medicine. Nanomaterials in Dental Medicine. 2023 Apr 4:141-57.

Green DW, Lai WF, Jung HS. Evolving marine biomimetics for regenerative dentistry. Marine drugs. 2014 May 13;12(5):2877-912.

Song F, Koo H, Ren D. Effects of material properties on bacterial adhesion and biofilm formation. Journal of dental research. 2015 Aug;94(8):1027-34.

Somacal DC, Manfroi FB, Monteiro MS, Oliveira SD, Bittencourt HR, Borges GA, Spohr AM. Effect of pH cycling followed by simulated toothbrushing on the surface roughness and bacterial adhesion of bulk-fill composite resins. Operative Dentistry. 2020 Mar 1;45(2):209-18.

Mokhtar H, Albaqami S, Albedairi F, Albader R, Alothaimin A, Alegayel S, Alkatheri M. Longevity and Clinical Performance of Direct Posterior Restorations.