Abstract

Dental implants made of titanium (Ti) material is recognized as the leading treatment option for edentulous patients’ rehabilitation, showing a high success rate and clinical longevity. However, dental implant surface acts as a platform for microbial adhesion and accumulation once exposed to the oral cavity. Biofilm formation on implant surfaces has been considered the main etiologic factor to induce inflammatory diseases, known as peri-implant mucositis and peri-implantitis; the latter being recognized as the key reason for late dental implant failure. Different factors, such as biofilm matrix production, source of carbohydrate exposure, and cross-kingdom interactions, have encouraged increased microbial accumulation on dental implants, leading to a microbiological community shift from a healthy to a pathogenic state, increasing inflammation and favoring tissue damage. These factors combined with the spatial organization of biofilms, reduced antimicrobial susceptibility, complex microbiological composition, and the irregular topography of implants hamper biofilm control and microbial killing. In spite of the well-known etiology, there is still no consensus regarding the best clinical protocol to control microbial accumulation on dental implant surfaces and treat peri-implant disease. In this sense, different coatings and Ti surface treatments have been proposed in order to reduce microbial loads and control polymicrobial infections on implantable devices. Therefore, this critical review aims to discuss the current evidence on biofilm accumulation on dental implants and central factors related to the pathogenesis process of implant-related infections. Moreover, the potential surface modifications with anti-biofilm properties for dental implant devices is discussed to shed light on further promising strategies to control peri-implantitis.

Key Words:
titanium; dental implant; biofilm; infection; coating

Resumo

Implantes dentários em titânio (Ti) são reconhecidos como principal modalidade terapêutica para a reabilitação oral de pacientes edêntulos, demonstrando uma alta taxa de sucesso e longevidade clínica. No entanto, após inserção no ambiente bucal, os implantes dentários agem como substrato para adesão e acúmulo microbiano. A formação de biofilmes em implantes dentários tem sido considerada o principal fator etiológico para induzir doenças inflamatórias conhecidas como mucosite peri-implantar e peri-implantite, sendo está última reconhecida como principal razão para falha tardia dos implantes dentários. Diferentes fatores têm sido atribuídos por promover o acúmulo microbiano em implantes dentários, levando a uma mudança microbiológica e favorecendo o dano tecidual, como a matriz do biofilme, exposição a carboidratos e interação entre reinos. Esses fatores combinados com a organização espacial de biofilmes, reduzida suscetibilidade microbiana, complexa composição microbiológica e a superfície irregular dos implantes dificultam o controle do biofilme e a morte microbiana. Apesar da etiologia bem conhecida, ainda não há consenso sobre o melhor protocolo clínico para controlar o acúmulo microbiano nas superfícies dos implantes dentários e tratar a doença peri-implantar. Nesse sentido, diferentes coberturas e tratamentos de superfície no Ti têm sido desenvolvidos objetivando a redução dos níveis microbianos e o controle das infecções polimicrobianas em implantes. Portanto, essa revisão crítica objetiva discutir a atual evidência em relação ao acúmulo de biofilmes em implantes dentários e fatores chave relacionados ao processo patogênico das infecções peri-implantares. Além disso, o potencial de alterações de superfícies com propriedades antimicrobianas para implantes dentários é discutido para ressaltar futuras estratégias promissoras no controle da peri-implantite.

Introduction

Titanium (Ti) has a long history as a pioneering material for dental implant production, being widely used to replace missing teeth and re-stablish masticatory, occlusal, and esthetic functions ¹1. Adell R, Lekholm U, Rockler B, Brånemark PI. A 15-year study of osseointegrated implants in the treatment of the edentulous jaw. Int J Oral Surg. 1981;10:387-416.^,22. Brånemark PI, Hansson BO, Adell R, Breine U, Lindström J, Hallén O, et al. Osseointegrated implants in the treatment of the edentulous jaw. Experience from a 10-year period. Scand J Plast Reconstr Surg Suppl. 1977;16:1-132.. Although Ti-based dental implants are a well-established treatment option with a high long-term survival rate (> 92%) ³3. Frisch E, Wild V, Ratka-Krüger P, Vach K, Sennhenn-Kirchner S. Long-term results of implants and implant-supported prostheses under systematic supportive implant therapy: A retrospective 25-year study. Clin Implant Dent Relat Res. 2020;22:689-696.^,44. Howe M-S, Keys W, Richards D. Long-term (10-year) dental implant survival: A systematic review and sensitivity meta-analysis. J Dent. 2019;84:9-21., Ti material is susceptible to the wear/corrosion (i.e. tribocorrosion) process ⁵5. Costa RC, Abdo VL, Mendes PHC, Mota-Veloso I, Bertolini M, Mathew MT, et al. Microbial Corrosion in Titanium-Based Dental Implants: How Tiny Bacteria Can Create a Big Problem? J Bio Tribo Corros. 2021;7:136.^,66. Dini C, Costa RC, Sukotjo C, Takoudis CG, Mathew MT, Barão VAR. Progression of Bio-Tribocorrosion in Implant Dentistry. Front Mech Eng. 2020; 6. and constant microbial challenge ⁷7. Lang NP, Brägger U, Walther D, Beamer B, Kornman KS. Ligature-induced peri-implant infection in cynomolgus monkeys. I. Clinical and radiographic findings. Clin Oral Implants Res. 1993;4:2-11.^,88. Mombelli A, Décaillet F. The characteristics of biofilms in peri-implant disease. J Clin Periodontol. 2011;38 Suppl 11:203-213. in the oral environment. Based on recent consensus reports ⁹9. Berglundh T, Armitage G, Araujo MG, Avila‐Ortiz G, Blanco J, Camargo PM, et al. Peri-implant diseases and conditions: Consensus report of workgroup 4 of the 2017 World Workshop on the Classification of Periodontal and Peri-Implant Diseases and Conditions. Journal of Clinical Periodontology. 2018;45:S286-91.^,1010. Schwarz F, Alcoforado G, Guerrero A, Jönsson D, Klinge B, Lang N, et al. Peri-implantitis: Summary and consensus statements of group 3. The 6th EAO Consensus Conference 2021. Clinical Oral Implants Research. 2021;32:245-253., biofilm-related to dental implants is the main etiological factor to induce implant-related infections, named peri-implant mucositis and peri-implantitis. These pathologic conditions increase the risk of late implant failures ¹¹11. Daubert DM, Weinstein BF. Biofilm as a risk factor in implant treatment. Periodontology 2000. 2019;81:29-40., thus being a relevant problem to oral health, especially in edentulous patients ¹²12. Schwendicke F, Tu Y-K, Stolpe M. Preventing and Treating Peri-Implantitis: A Cost-Effectiveness Analysis. J Periodontol. 2015;86:1020-9.. All non-surgical therapies in these cases are challenging because of the difficult access to treat the disease sites, the complex micro and macro topography of implant surface, and because of how tightly adhered these biofilms are to dental implant surfaces ⁸8. Mombelli A, Décaillet F. The characteristics of biofilms in peri-implant disease. J Clin Periodontol. 2011;38 Suppl 11:203-213.^,1313. Derks J, Tomasi C. Peri-implant health and disease. A systematic review of current epidemiology. J Clin Periodontol. 2015;42:S158-171.. This may explain the ineffectiveness of non-surgical treatments for peri-implantitis cases ¹⁴14. Ntrouka VI, Slot DE, Louropoulou A, Van der Weijden F. The effect of chemotherapeutic agents on contaminated titanium surfaces: a systematic review. Clin Oral Implants Res. 2011;22:681-90.^,1515. Suárez-López Del Amo F, Yu S-H, Wang H-L. Non-Surgical Therapy for Peri-Implant Diseases: a Systematic Review. J Oral Maxillofac Res. 2016;7:e13., even associated with systemic antibiotics ¹⁶16. Shibli JA, Ferrari DS, Siroma RS, Figueiredo LC de, Faveri M de, Feres M, et al. Microbiological and clinical effects of adjunctive systemic metronidazole and amoxicillin in the non-surgical treatment of peri-implantitis: 1 year follow-up. Brazilian Oral Research. 2019;33.. Therefore, to prevent and control microbial adhesion and accumulation on dental implant surfaces, designing antimicrobial Ti surface modifications has attracted researchers' attention visualizing the possibility of avoiding these infections, rather than treating them ¹⁷17. Alipal J, Mohd Pu’ad NAS, Nayan NHM, Sahari N, Abdullah HZ, Idris MI, et al. An updated review on surface functionalisation of titanium and its alloys for implants applications. Materials Today: Proceedings. 2021.^,1818. Xue T, Attarilar S, Liu S, Liu J, Song X, Li L, et al. Surface Modification Techniques of Titanium and its Alloys to Functionally Optimize Their Biomedical Properties: Thematic Review. Front Bioeng Biotechnol. 2020;8:603072..

Besides improving peri-implant bone healing process, Ti surface modifications can promote the desired anti-biofilm effects ¹⁹19. Souza JGS, Bertolini MM, Costa RC, Nagay BE, Dongari-Bagtzoglou A, Barão VAR. Targeting implant-associated infections: titanium surface loaded with antimicrobial. iScience. 22 de janeiro de 2021;24:102008.. Antimicrobial compounds such as bioactive elements, metallic nanoparticles and ions, antibiotics, anti-infective substances, antimicrobial peptides (AMPs), and therapeutic polymers have been routinely incorporated onto Ti surfaces by numerous deposition methods ²⁰20. Chouirfa H, Bouloussa H, Migonney V, Falentin-Daudré C. Review of titanium surface modification techniques and coatings for antibacterial applications. Acta Biomater. 2019;83:37-54.. Previous studies ²¹21. Ao H, Yang S, Nie B, Fan Q, Zhang Q, Zong J, et al. Improved antibacterial properties of collagen I/hyaluronic acid/quaternized chitosan multilayer modified titanium coatings with both contact-killing and release-killing functions. J Mater Chem B. 2019;7:1951-1961.^,2222. Chen J, Shi X, Zhu Y, Chen Y, Gao M, Gao H, et al. On-demand storage and release of antimicrobial peptides using Pandora’s box-like nanotubes gated with a bacterial infection-responsive polymer. Theranostics. 2020;10:109-122.^,2323. Gao Q, Feng T, Huang D, Liu P, Lin P, Wu Y, et al. Antibacterial and hydroxyapatite-forming coating for biomedical implants based on polypeptide-functionalized titania nanospikes. Biomater Sci. 2019;8:278-289.^,2424. Hong L, Liu X, Tan L, Cui Z, Yang X, Liang Y, et al. Rapid Biofilm Elimination on Bone Implants Using Near-Infrared-Activated Inorganic Semiconductor Heterostructures. Advanced Healthcare Materials. 2019;8:1900835.^,2525. Huang B, Tan L, Liu X, Li J, Wu S. A facile fabrication of novel stuff with antibacterial property and osteogenic promotion utilizing red phosphorus and near-infrared light. Bioactive Materials. 2019;4:17-21.^,26 26. Li D, Li Y, Shrestha A, Wang S, Wu Q, Li L, et al. Effects of Programmed Local Delivery from a Micro/Nano-Hierarchical Surface on Titanium Implant on Infection Clearance and Osteogenic Induction in an Infected Bone Defect. Adv Healthc Mater. 2019;8:e1900002. have confirmed the promising results of these emerging surfaces to control biofilm accumulation and microbial infections in animal models. However, thus far, the market lacks Ti surface modifications with trustworthy antimicrobial properties for dental implant applications in the clinical setting ²⁷27. Costa RC, Nagay BE, Bertolini M, Costa-Oliveira BE, Sampaio AA, Retamal-Valdes B, et al. Fitting pieces into the puzzle: The impact of titanium-based dental implant surface modifications on bacterial accumulation and polymicrobial infections. Advances in Colloid and Interface Science. 2021;298:102551..

Therefore, this critical review aims to offer an updated perspective of implant-related infections and the development of Ti surface modifications with desirable antimicrobial properties for dental implant applications. In addition, we prospect this review of available scientific evidence will stimulate researchers to rationally engineer safer implant surfaces, focusing on translation to real-world applications.

Biofilm accumulation on dental implants: a villain to be defeated

Biofilms are well-organized microbial communities enmeshed in a three-dimensional extracellular matrix ²⁸28. Bowen WH, Burne RA, Wu H, Koo H. Oral Biofilms: Pathogens, Matrix, and Polymicrobial Interactions in Microenvironments. Trends in Microbiology. 2018; 26:229-242.^,2929. Costerton JW, Lewandowski Z, Caldwell DE, Korber DR, Lappin-Scott HM. Microbial biofilms. Annu Rev Microbiol. 1995;49:711-745., which create a proper environment and architecture with numerous benefits to colonizing species, such as protection against antimicrobials, improved co-aggregation, microbial metabolism, and interaction properties ²⁹29. Costerton JW, Lewandowski Z, Caldwell DE, Korber DR, Lappin-Scott HM. Microbial biofilms. Annu Rev Microbiol. 1995;49:711-745.^,3030. Karygianni L, Ren Z, Koo H, Thurnheer T. Biofilm Matrixome: Extracellular Components in Structured Microbial Communities. Trends Microbiol. 2020;28:668-81.. Biofilm accumulation on biotic and abiotic surfaces is a multifaceted process mediated by the materials’ surface properties, the host response, and environmental conditions ³¹31. Song F, Koo H, Ren D. Effects of Material Properties on Bacterial Adhesion and Biofilm Formation. J Dent Res. 2015;94:1027-34.. Therefore, indigenous microorganisms from the oral microbiome living in a mutual state with the host and adhered on any surface in the oral cavity are directly affected by local or host environmental changes, which may lead to the overgrowth of pathogenic species, and often lead to the development of oral diseases ³²32. Dewhirst FE, Chen T, Izard J, Paster BJ, Tanner ACR, Yu W-H, et al. The human oral microbiome. J Bacteriol. 2010;192:5002-17.. Hence, any surface inserted in the oral environment, such as dental implants, can act as an additional substrate for microbial adhesion and accumulation ⁸8. Mombelli A, Décaillet F. The characteristics of biofilms in peri-implant disease. J Clin Periodontol. 2011;38 Suppl 11:203-213..

Protein adsorption on biomaterials has been pointed as the initial biological response in the human body, and this process is responsible for interceding successive cellular events, such as microbial and host cell adhesion ³³33. Rabe M, Verdes D, Seeger S. Understanding protein adsorption phenomena at solid surfaces. Advances in Colloid and Interface Science. 2011;162:87-106.. Interestingly, the chemical and physical properties of Ti surfaces directly affect the proteomic profile of proteins adsorbed from saliva and plasma ³⁴34. Pantaroto HN, Amorim KP, Matozinho Cordeiro J, Souza JGS, Ricomini-Filho AP, Rangel EC, et al. Proteome analysis of the salivary pellicle formed on titanium alloys containing niobium and zirconium. Biofouling. 2019;35:173-86.^,3535. Souza JGS, Bertolini M, Costa RC, Lima CV, Barão VAR. Proteomic profile of the saliva and plasma protein layer adsorbed on Ti-Zr alloy: the effect of sandblasted and acid-etched surface treatment. Biofouling. 2020;36:428-41.. Therefore, important differences between oral surfaces and biomaterial surfaces are expected for protein adsorption and for further microbial adhesion, thus the comprehensive knowledge gained from microbial accumulation on dental surfaces cannot be simply transferred to the dental implant field before being tested experimentally.

Knowing that the oral cavity hosts nearly a thousand bacterial species detectable by high throughput 16S rRNA gene sequencing ³²32. Dewhirst FE, Chen T, Izard J, Paster BJ, Tanner ACR, Yu W-H, et al. The human oral microbiome. J Bacteriol. 2010;192:5002-17., dental implants will be exposed to a complex community of microbes once coated by the initial saliva/plasma protein layer. Thus, although teeth and implants share the same oral environment, they can show differences in their microbial ecosystems, mainly in terms of microbial species ³⁶36. Dabdoub SM, Tsigarida AA, Kumar PS. Patient-specific analysis of periodontal and peri-implant microbiomes. J Dent Res. d 2013;92:168S-75S.. On dental implants, Streptococcus, Fusobacterium, and Capnocytophaga species have been described as initial colonizers immediately after implant placement ³⁷37. Fürst MM, Salvi GE, Lang NP, Persson GR. Bacterial colonization immediately after installation on oral titanium implants. Clinical Oral Implants Research. 2007;18:501-8., whether in teeth early plaque formation involves several streptococcal species, as well as nonstreptococcal species, such as Neisseria, Rothia, and Gemella. ³⁸38. Diaz PI, Chalmers NI, Rickard AH, Kong C, Milburn CL, Palmer RJ, et al. Molecular characterization of subject-specific oral microflora during initial colonization of enamel. Appl Environ Microbiol. 2006;72:2837-48.^,3939. Ihara Y, Takeshita T, Kageyama S, Matsumi R, Asakawa M, Shibata Y, et al. Identification of Initial Colonizing Bacteria in Dental Plaques from Young Adults Using Full-Length 16S rRNA Gene Sequencing. mSystems. 2019;4:e00360-19.. Thus, interactions among different species and late colonizers, recognized as the co-aggregation process, which will drive biofilm maturation, can significantly differ from dental implants and teeth, being highly site specific. Once mature, biofilms form a well-established and steady ‘climax community’ ⁴⁰40. Marsh PD, Moter A, Devine DA. Dental plaque biofilms: communities, conflict and control. Periodontol 2000. 2011;55:16-35.^,4141. Socransky SS, Haffajee AD. Dental biofilms: difficult therapeutic targets. Periodontol2000. 2002;28:12-55. known to be very stable over time ⁴²42. Rosier BT, Marsh PD, Mira A. Resilience of the Oral Microbiota in Health: Mechanisms That Prevent Dysbiosis. J Dent Res. 2018;97:371-80..

Implant-related infections: a prevalent and challenging problem

According to the last classification of dental implant diseases published in 2018, the current evidence shows that polymicrobial biofilms are responsible for inducing inflammatory disease processes on peri-implant sites named as peri-implant mucositis and peri-implantitis ⁹9. Berglundh T, Armitage G, Araujo MG, Avila‐Ortiz G, Blanco J, Camargo PM, et al. Peri-implant diseases and conditions: Consensus report of workgroup 4 of the 2017 World Workshop on the Classification of Periodontal and Peri-Implant Diseases and Conditions. Journal of Clinical Periodontology. 2018;45:S286-91.. While peri-implant mucositis is characterized by reversible inflammation in the dental implant surrounding mucosa without alveolar bone loss, peri-implantitis results from the progressive loss of supporting bone in which implants are anchored ⁹9. Berglundh T, Armitage G, Araujo MG, Avila‐Ortiz G, Blanco J, Camargo PM, et al. Peri-implant diseases and conditions: Consensus report of workgroup 4 of the 2017 World Workshop on the Classification of Periodontal and Peri-Implant Diseases and Conditions. Journal of Clinical Periodontology. 2018;45:S286-91.^,1010. Schwarz F, Alcoforado G, Guerrero A, Jönsson D, Klinge B, Lang N, et al. Peri-implantitis: Summary and consensus statements of group 3. The 6th EAO Consensus Conference 2021. Clinical Oral Implants Research. 2021;32:245-253.. Therefore, implant-related infections, mainly peri-implantitis, have been considered the main reason for dental implant treatment failure, affecting from 40% to 22% of implants by peri-implant mucositis and peri-implantitis, respectively ⁴³43. Salvi GE, Cosgarea R, Sculean A. Prevalence and Mechanisms of Peri-implant Diseases. J Dent Res. 2017;96:31-7..

Importantly, a recent adaptation from the “ecological plaque hypothesis” on tooth surfaces was used to depict a switch from a healthy to a disease state in the peri-implant mucosa and bone tissues ¹⁹19. Souza JGS, Bertolini MM, Costa RC, Nagay BE, Dongari-Bagtzoglou A, Barão VAR. Targeting implant-associated infections: titanium surface loaded with antimicrobial. iScience. 22 de janeiro de 2021;24:102008.. This biological hypothesis, based on the current evidence, describes the different factors that may trigger/contribute to disrupting the symbiotic state of implant-related biofilms, leading to an overgrowth of species with pathogenic potential, triggering inflammatory processes, or contributing to disease progression ¹⁹19. Souza JGS, Bertolini MM, Costa RC, Nagay BE, Dongari-Bagtzoglou A, Barão VAR. Targeting implant-associated infections: titanium surface loaded with antimicrobial. iScience. 22 de janeiro de 2021;24:102008.. We and others have shown that several factors may contribute to this process, such as carbohydrate exposure that favors biofilm growth matrix production, and cross-kingdom interaction between bacteria and Candida albicans, all that leading to subsequent environmental changes and a higher proinflammatory response ⁴⁴44. Costa RC, Souza JGS, Bertolini M, Retamal‐Valdes B, Feres M, Barão VAR. Extracellular biofilm matrix leads to microbial dysbiosis and reduces biofilm susceptibility to antimicrobials on titanium biomaterial: An in vitro and in situ study. Clinical Oral Implants Research. 2020;31:1173-86.^,4545. Souza JGS, Cury JA, Ricomini Filho AP, Feres M, Faveri M de, Barão VAR. Effect of sucrose on biofilm formed in situ on titanium material. J Periodontol. 2019;90:141-8.^,4646. Souza JGS, Bertolini M, Thompson A, Mansfield JM, Grassmann AA, Maas K, et al. Role of glucosyltransferase R in biofilm interactions between Streptococcus oralis and Candida albicans. ISME J. 2020;14:1207-22.. These factors, combined with the complex architecture of oral biofilms, wide microbiological composition, reduced antimicrobial susceptibility, and the irregular topography of dental implants, make it a complex disease to be controlled and eradicated ⁴⁷47. Arciola CR, Campoccia D, Montanaro L. Implant infections: adhesion, biofilm formation and immune evasion. Nature Reviews Microbiology. 2018;16:397-409.. Furthermore, it may explain the non-consensus regarding the optimal clinical protocol to treat peri-implantitis and the ineffectiveness of non-surgical treatments ¹⁵15. Suárez-López Del Amo F, Yu S-H, Wang H-L. Non-Surgical Therapy for Peri-Implant Diseases: a Systematic Review. J Oral Maxillofac Res. 2016;7:e13.^,4848. Heitz-Mayfield LJA, Mombelli A. The therapy of peri-implantitis: a systematic review. Int J Oral Maxillofac Implants. 2014;29Suppl:325-45.. Therefore, coatings and changes on chemical/physical properties of Ti surfaces are emerging as promising approaches to improve the antibacterial properties potential of Ti-based implantable devices and to prevent implant-related infections ²⁷27. Costa RC, Nagay BE, Bertolini M, Costa-Oliveira BE, Sampaio AA, Retamal-Valdes B, et al. Fitting pieces into the puzzle: The impact of titanium-based dental implant surface modifications on bacterial accumulation and polymicrobial infections. Advances in Colloid and Interface Science. 2021;298:102551..

Implant surface engineering to control biofilm-related to dental implants

Ti surface modifications have been widely proposed to improve the quality of the osseointegration process and/or exert an antimicrobial property to avoid implant infections ¹⁷17. Alipal J, Mohd Pu’ad NAS, Nayan NHM, Sahari N, Abdullah HZ, Idris MI, et al. An updated review on surface functionalisation of titanium and its alloys for implants applications. Materials Today: Proceedings. 2021.^,4949. Florea DA, Albuleț D, Grumezescu AM, Andronescu E. Surface modification - A step forward to overcome the current challenges in orthopedic industry and to obtain an improved osseointegration and antimicrobial properties. Materials Chemistry and Physics. 2020;243:122579.. Generally, implant surface modifications change the material topography by macro-, micro-, or nano-texturization with or without the incorporation of antimicrobial compounds ¹⁹19. Souza JGS, Bertolini MM, Costa RC, Nagay BE, Dongari-Bagtzoglou A, Barão VAR. Targeting implant-associated infections: titanium surface loaded with antimicrobial. iScience. 22 de janeiro de 2021;24:102008.^,19). These implant surface modifications can be performed by numerous techniques, which may be mechanical, physical, chemical, or a combination of all ²⁰20. Chouirfa H, Bouloussa H, Migonney V, Falentin-Daudré C. Review of titanium surface modification techniques and coatings for antibacterial applications. Acta Biomater. 2019;83:37-54.. In terms of antimicrobial properties, four major surface mechanisms should be considered: i) microbial biofilm modulation (bioactive surfaces); ii) microbial repelling/non-adhering properties (antifouling surfaces), iii) contact-killing or release-killing compounds (antimicrobial-loaded surfaces), and iv) ‘on-demand’ antimicrobial agent delivery (smart surfaces) ⁴⁹49. Florea DA, Albuleț D, Grumezescu AM, Andronescu E. Surface modification - A step forward to overcome the current challenges in orthopedic industry and to obtain an improved osseointegration and antimicrobial properties. Materials Chemistry and Physics. 2020;243:122579.^,5050. Yuan Z, He Y, Lin C, Liu P, Cai K. Antibacterial surface design of biomedical titanium materials for orthopedic applications. Journal of Materials Science and Technology. 2021;78:51-67.. For the purpose of this review, Ti surface treatments were classified based on the above-mentioned antimicrobial mechanisms, as previously described elsewhere ²⁷27. Costa RC, Nagay BE, Bertolini M, Costa-Oliveira BE, Sampaio AA, Retamal-Valdes B, et al. Fitting pieces into the puzzle: The impact of titanium-based dental implant surface modifications on bacterial accumulation and polymicrobial infections. Advances in Colloid and Interface Science. 2021;298:102551..

Bioactive implant surfaces

The initial research focus on implant surfaces was the so-called ‘bioactive surfaces’ ⁵¹51. Meng H-W, Chien EY, Chien H-H. Dental implant bioactive surface modifications and their effects on osseointegration: a review. Biomarker Research. 2016;4:24.. In these surfaces, functional compounds [e.g., Ca, PO₄³⁻, Si, Mg, Zn, Na, N, C, Ta, Se, hydroxyapatite, bioactive glasses, growth factors, and others] were incorporated onto the Ti surface, changing the material surface properties and directly improving its biological responses ⁵²52. López-Valverde N, Flores-Fraile J, Ramírez JM, Sousa BM de, Herrero-Hernández S, López-Valverde A. Bioactive Surfaces vs. Conventional Surfaces in Titanium Dental Implants: A Comparative Systematic Review. J Clin Med. 2020;9(7).. Compared to control surfaces (machined, acid etching, or grit-blasting Ti surfaces), bioactive surfaces have revealed good mechanical/tribological behavior ⁵³53. Marques I da SV, da Cruz NC, Landers R, Yuan JC-C, Mesquita MF, Sukotjo C, et al. Incorporation of Ca, P, and Si on bioactive coatings produced by plasma electrolytic oxidation: The role of electrolyte concentration and treatment duration. Biointerphases. 2015;10:041002., superior anti-corrosion performance ⁵⁴54. Beline T, de Almeida AB, Azevedo-Neto NF, Matos AO, Ricomini-Filho AP, Sukotjo C, et al. β-Ta2O5 thin film for implant surface modification triggers superior anti-corrosion performance and cytocompatibility of titanium. Applied Surface Science. 2020;520:146326., with bone cell stimulatory capacity ⁵⁵55. Santos-Coquillat A, Mohedano M, Martinez-Campos E, Arrabal R, Pardo A, Matykina E. Bioactive multi-elemental PEO-coatings on titanium for dental implant applications. Materials Science and Engineering: C. 2019;97:738-752., and faster in vitro apatite growth ⁵⁶56. Xiu P, Jia Z, Lv J, Yin C, Cheng Y, Zhang K, et al. Tailored Surface Treatment of 3D Printed Porous Ti6Al4V by Microarc Oxidation for Enhanced Osseointegration via Optimized Bone In-Growth Patterns and Interlocked Bone/Implant Interface. ACS Appl Mater Interfaces. 2016;8:17964-75.. Bioactive surfaces also promote higher bone matrix deposition at the implant-tissue interface, as well-documented in animal models ⁵⁷57. Polo TOB, Silva WPP, Momesso GAC, Lima-Neto TJ, Barbosa S, Cordeiro JM, et al. Plasma Electrolytic Oxidation as a Feasible Surface Treatment for Biomedical Applications: an in vivo study. Sci Rep. 2020;10:10000.^,5858. Romero-Ruiz MM, Gil-Mur FJ, Ríos-Santos JV, Lázaro-Calvo P, Ríos-Carrasco B, Herrero-Climent M. Influence of a Novel Surface of Bioactive Implants on Osseointegration: A Comparative and Histomorfometric Correlation and Implant Stability Study in Minipigs. International Journal of Molecular Sciences. 2019;20:2307.. Although bioactive surfaces can be indicated to reduce the initial osseointegration period ⁵²52. López-Valverde N, Flores-Fraile J, Ramírez JM, Sousa BM de, Herrero-Hernández S, López-Valverde A. Bioactive Surfaces vs. Conventional Surfaces in Titanium Dental Implants: A Comparative Systematic Review. J Clin Med. 2020;9(7)., which is clinically relevant for implant therapy with immediate/early loading protocols ⁵⁹59. Borges GA, Costa RC, Nagay BE, Magno MB, Maia LC, Barão VAR, et al. Long-term outcomes of different loading protocols for implant-supported mandibular overdentures: A systematic review and meta-analysis. The Journal of Prosthetic Dentistry. 2021;125:732-745., these surfaces have limited anti-biofilm effect due to the absence of antimicrobial agents. Currently, the major challenge is incorporating antimicrobial elements into the Ti material able to promote a reliable and long-term antimicrobial effect without losing their bioactive capabilities overtime or reaching sub-inhibitory concentrations which can favor the emergence of hyper-resistant strains, creating a much bigger issue ⁶⁰60. Bruchmann J, Kirchen S, Schwartz T. Sub-inhibitory concentrations of antibiotics and wastewater influencing biofilm formation and gene expression of multi-resistant Pseudomonas aeruginosa wastewater isolates. Environ Sci Pollut Res Int. junho de2013;20:3539-3549.^,6161. Chueca B, Berdejo D, Gomes-Neto NJ, Pagán R, García-Gonzalo D. Emergence of Hyper-Resistant Escherichia coli MG1655 Derivative Strains after Applying Sub-Inhibitory Doses of Individual Constituents of Essential Oils. Front Microbiol. 2016;7:273..

Regarding the antimicrobial attributes of bioactive surfaces, researchers are not only thinking about developing surfaces that could kill bacteria, but also creating a positive effect on the composition of the attached biofilm by selecting health associated bacterial species ⁵⁰50. Yuan Z, He Y, Lin C, Liu P, Cai K. Antibacterial surface design of biomedical titanium materials for orthopedic applications. Journal of Materials Science and Technology. 2021;78:51-67.. In this context, our group recently engineered a bioactive glass-based coating by plasma electrolytic oxidation (abbreviated as PEO-BG), which was able to improve the biological responses along with promoting positive polymicrobial biofilm modulation ⁶²62. Costa RC, Souza JGS, Cordeiro JM, Bertolini M, de Avila ED, Landers R, et al. Synthesis of bioactive glass-based coating by plasma electrolytic oxidation: Untangling a new deposition pathway toward titanium implant surfaces. J Colloid Interface Sci. 2020;579:680-698.. PEO-BG induced a microbiological shift on the implant surface colonization, promoting a decrease in diversity and a gradual depletion of pathogenic associated bacteria and an enrichment of the healthy resident microbial community (Figure 1). We showed that the surface chemistry and topography patterns of PEO-BG surface led to a shift from disease- to the health-associated microbial community, which once stable, could prevent implant-related infections ⁶³63. Belibasakis GN, Manoil D. Microbial Community-Driven Etiopathogenesis of Peri-Implantitis. J Dent Res. 2021;100(1):21-28.. Surfaces with a biofilm modulation mechanism also seem promising to avoid the ever-increasing problem of bacterial resistance on implanted biomaterials ⁶⁴64. Haque M, Sartelli M, McKimm J, Abu Bakar M. Health care-associated infections - an overview. Infect Drug Resist. 2018;11:2321-2333. and are worth researching more extensively to obtain in-depth exploration for posterior use in patients.

Figure 1.
Overview of newly developed bioactive glass-based coating for implant application with microbial biofilm modulationattributes. (A) Representative confocal images (50× magnification) revelated the complex surface topography of the PEO-BG surface (i.e., “glass grain-like”) compared to control surfaces such as machined and SLA. Surface chemistry was evaluated using energy-dispersive spectroscopy, showing stoichiometric proportions similar to 45S5 bioglass on Ti surface (data not shown). Microbiological analysis was performed after microbial adhesion (2 h) and biofilm formation (24 h) with human saliva as the microbial inoculum. Although the number of viable bacterial cells visualized by confocal imagens (live cells were stained in green by SYTO-9; scale bars 50 µm) did not differ considerably between control groups during microbial adhesion (B), we untangled that the bacterial community profile adhered to the PEO-BG surface was more compatible with the resident microbiome by DNA-DNA checkboard method (C). Reprinted adapted from Costa et al. 2020 [62]; Copyright (2020);

Antifouling implant surfaces

Since microbial adhesion is the first step of biofilm formation, designing antifouling surfaces can help to avoid implant-related infections from the beginning, creating a biofilm free surface ⁶⁵65. Song F, Koo H, Ren D. Effects of Material Properties on Bacterial Adhesion and Biofilm Formation. J Dent Res. 2015;94(8):1027-1034.. Implant surface properties such as wettability, surface roughness, and topography patterns play an essential role in microbial-surface interactions and directly affect bacterial adherence and colonization ⁶⁶66. Lee SW, Phillips KS, Gu H, Kazemzadeh-Narbat M, Ren D. How microbes read the map: Effects of implant topography on bacterial adhesion and biofilm formation. Biomaterials. 2021;268:120595.. For instance, increasing a surface's hydrophobicity can diminish the adhesion forces between bacteria and implant surface, thus avoiding the micro-organism ability to reach the surface and form biofilms ⁶⁵65. Song F, Koo H, Ren D. Effects of Material Properties on Bacterial Adhesion and Biofilm Formation. J Dent Res. 2015;94(8):1027-1034.. However, the main concern about these antifouling surfaces in the implantology field is the possible negative impact for initial protein adsorption and, importantly, for host cell adhesion processes ⁶⁷67. Elias CN, Oshida Y, Lima JHC, Muller CA. Relationship between surface properties (roughness, wettability and morphology) of titanium and dental implant removal torque. J Mech Behav Biomed Mater. 2008;1:234-42.^,6868. Falde EJ, Yohe ST, Colson YL, Grinstaff MW. Superhydrophobic materials for biomedical applications. Biomaterials. 2016;104:87-103.. Remarkably, Souza et al.²⁰²⁰20. Chouirfa H, Bouloussa H, Migonney V, Falentin-Daudré C. Review of titanium surface modification techniques and coatings for antibacterial applications. Acta Biomater. 2019;83:37-54.^{) (69}69. Souza JGS, Bertolini M, Costa RC, Cordeiro JM, Nagay BE, de Almeida AB, et al. Targeting Pathogenic Biofilms: Newly Developed Superhydrophobic Coating Favors a Host-Compatible Microbial Profile on the Titanium Surface. ACS Appl Mater Interfaces. 2020;12:10118-29., developed a one-step protocol based on a low-pressure glow discharge plasma technology, to generate a superhydrophobic coating (water contact angle over 150°) for the Ti surface able to dramatically reduce the initial bacterial adhesion while allowing human fibroblast cell colonization and proliferation. This newly developed antifouling surface also allowed bacterial killing by direct contact with the oral bacteria attached to the Ti surface, tested in vitro and in situ (~ 8-fold decrease vs. non-treated surface) (Figure 2), reducing the load of bacterial pathogens associated with peri-implantitis. Moreover, this surface favored fibroblasts cell adhesion (at 1, 3, and 4 days of culture), probably due to the high surface roughness, as previously reviewed ⁶⁵65. Song F, Koo H, Ren D. Effects of Material Properties on Bacterial Adhesion and Biofilm Formation. J Dent Res. 2015;94(8):1027-1034.. Based on Wenzel and Cassel-Baxter principles ⁶⁸68. Falde EJ, Yohe ST, Colson YL, Grinstaff MW. Superhydrophobic materials for biomedical applications. Biomaterials. 2016;104:87-103., the surface hydrophobicity is determined primarily by surface roughness; therefore, this surface is an example in which the Ti surface modification led to altered physicochemical properties (highly roughened surfaces; Ra > 3.0 μm) with direct antimicrobial effect. In addition, others have shown that bactericidal effect is more pronounced on surfaces with taller structures ⁷⁰70. Spengler C, Nolle F, Mischo J, Faidt T, Grandthyll S, Thewes N, et al. Strength of bacterial adhesion on nanostructured surfaces quantified by substrate morphometry. Nanoscale. 2019;11:19713-22..

Figure 2
One-step superhydrophobic coating synthesized by low-pressure glow discharge plasma technology on Ti biomaterial. (A) Two- and three-dimensional images (150× magnification) by 3D laser scanning confocal microscopy showing the differences in the topography patterns and surface area between surfaces (non-treated control and treated). Polymicrobial biofilm was formed for 24 h using human saliva as the microbial inoculum to check the antifouling property. (B) Scanning electron microscopy (1,500× magnification) and (C) confocal images (50 μm; green - live bacteria cells stained using SYTO-9) confirmed that superhydrophobic coating dramatically reduces the microbial biofilm adhesion on Ti surface in vitro. Reprinted adapted from Sousa et al. 2020 [69]; Copyright ²⁰²⁰20. Chouirfa H, Bouloussa H, Migonney V, Falentin-Daudré C. Review of titanium surface modification techniques and coatings for antibacterial applications. Acta Biomater. 2019;83:37-54.; with permission from American Chemical Society (License number: 5084191501822).

In addition to superhydrophobic surfaces, nature-inspired biomimetic surfaces also have strong antifouling activities to prevent microbial accumulation ⁷¹71. Linklater DP, Baulin VA, Juodkazis S, Crawford RJ, Stoodley P, Ivanova EP. Mechano-bactericidal actions of nanostructured surfaces. Nat Rev Microbiol. 2021;19:8-22.. In terms of topography patterns, there is a relationship between the size scale of the bacteria and the characteristic dimensions of the surface texture to promote the anti-biofilm effect ⁷²72. Puckett SD, Taylor E, Raimondo T, Webster TJ. The relationship between the nanostructure of titanium surfaces and bacterial attachment. Biomaterials. 2010;31:706-13.. Overall bacteria preferentially adhere to and colonize in the grooves and spaces of micro structured surfaces, but only if these recessed regions are larger than or approximately equal to their own size ²⁷27. Costa RC, Nagay BE, Bertolini M, Costa-Oliveira BE, Sampaio AA, Retamal-Valdes B, et al. Fitting pieces into the puzzle: The impact of titanium-based dental implant surface modifications on bacterial accumulation and polymicrobial infections. Advances in Colloid and Interface Science. 2021;298:102551.^,6666. Lee SW, Phillips KS, Gu H, Kazemzadeh-Narbat M, Ren D. How microbes read the map: Effects of implant topography on bacterial adhesion and biofilm formation. Biomaterials. 2021;268:120595., as the size of the nanostructures increases, the bacterial adhesion forces decrease ⁷⁰70. Spengler C, Nolle F, Mischo J, Faidt T, Grandthyll S, Thewes N, et al. Strength of bacterial adhesion on nanostructured surfaces quantified by substrate morphometry. Nanoscale. 2019;11:19713-22.. In this sense, nanostructured Ti surfaces have been associated with antifouling and bacteriostatic effects by repelling the bacteria that cannot find sites for initial attachment ⁷²72. Puckett SD, Taylor E, Raimondo T, Webster TJ. The relationship between the nanostructure of titanium surfaces and bacterial attachment. Biomaterials. 2010;31:706-13.. Among the nature-inspired biomimetic surfaces, the creation of nanopillars ⁷³73. Loya MC, Brammer KS, Choi C, Chen L-H, Jin S. Plasma-induced nanopillars on bare metal coronary stent surface for enhanced endothelialization. Acta Biomaterialia. 2010;6:4589-95., nanocolumns ⁷⁴74. Sekiguchi H, Higashi Y, Yamane K, Wakahara A, Okada H, Kishino K. Fabrication and optical properties of regularly arranged GaN-based nanocolumns on Si substrate. Journal of Vacuum Science & Technology B. 2019;37:031207., nanowires ⁷⁵75. Peng K, Xu Y, Wu Y, Yan Y, Lee S-T, Zhu J. Aligned single-crystalline Si nanowire arrays for photovoltaic applications. Small. 2005;1:1062-1067., nanospikes ⁷⁶76. Yu R, Ching K-L, Lin Q, Leung S-F, Arcrossito D, Fan Z. Strong light absorption of self-organized 3-D nanospike arrays for photovoltaic applications. ACS Nano. 2011;5:9291-9298., spear-type ⁷⁷77. Cao Y, Su B, Chinnaraj S, Jana S, Bowen L, Charlton S, et al. Nanostructured titanium surfaces exhibit recalcitrance towards Staphylococcus epidermidis biofilm formation. Scientific Reports. 2018;8:1071., wing-like ⁷⁸78. Hasan J, Webb HK, Truong VK, Pogodin S, Baulin VA, Watson GS, et al. Selective bactericidal activity of nanopatterned superhydrophobic cicada Psaltoda claripennis wing surfaces. Appl Microbiol Biotechnol. 2013;97:9257-9262., and lotus-leaf-like ⁷⁹79. Truong VK, Webb HK, Fadeeva E, Chichkov BN, Wu AHF, Lamb R, et al. Air-directed attachment of coccoid bacteria to the surface of superhydrophobic lotus-like titanium. Biofouling. 2012;28:539-550. surfaces have potential to inhibited specific bacterial species (such as Streptococcus aureus and Escherichia coli) and represents a valuable strategy to be tested against oral polymicrobial biofilms related to dental implant surfaces using in vivo mechanistic studies.

Antimicrobial-loaded implant surfaces

Antimicrobial-loaded surfaces have been a major focus of implantology research in the last 20 years ⁸⁰80. Gollwitzer H, Ibrahim K, Meyer H, Mittelmeier W, Busch R, Stemberger A. Antibacterial poly(D,L-lactic acid) coating of medical implants using a biodegradable drug delivery technology. J Antimicrob Chemother. 2003;51:585-591.^,8181. Harris LG, Mead L, Müller-Oberländer E, Richards RG. Bacteria and cell cytocompatibility studies on coated medical grade titanium surfaces. J Biomed Mater Res A. 2006;78:50-58.^,8282. Norowski PA, Courtney HS, Babu J, Haggard WO, Bumgardner JD. Chitosan coatings deliver antimicrobials from titanium implants: a preliminary study. Implant Dent. 2011;20:56-67.. Numerous antimicrobial compounds [e.g., metallic nanoparticles and ions, antibiotics, anti-infective substances, antimicrobial peptides (AMPs), therapeutic polymers, and others] have been employed to attempt to improve Ti surfaces antimicrobial activities ¹⁷17. Alipal J, Mohd Pu’ad NAS, Nayan NHM, Sahari N, Abdullah HZ, Idris MI, et al. An updated review on surface functionalisation of titanium and its alloys for implants applications. Materials Today: Proceedings. 2021.. These antimicrobial surfaces can be achieved by one or multi-step process using several deposition techniques to ensure suitable bacteriostatic and bactericidal action (Figure 3) ²⁷27. Costa RC, Nagay BE, Bertolini M, Costa-Oliveira BE, Sampaio AA, Retamal-Valdes B, et al. Fitting pieces into the puzzle: The impact of titanium-based dental implant surface modifications on bacterial accumulation and polymicrobial infections. Advances in Colloid and Interface Science. 2021;298:102551.. Antimicrobial activity is achieved mainly via physical damage of the bacteria cell membrane ascribed to antimicrobial onto the surface (contact-killing) or their release in the local of infection with uptake into the bacterial cell (release-killing) ⁶⁶66. Lee SW, Phillips KS, Gu H, Kazemzadeh-Narbat M, Ren D. How microbes read the map: Effects of implant topography on bacterial adhesion and biofilm formation. Biomaterials. 2021;268:120595.. In fact, in laboratory studies, antimicrobial-loaded surfaces promote superior results in biofilm reduction than control surfaces ⁸³83. Cordeiro JM, Nagay BE, Dini C, Souza JGS, Rangel EC, da Cruz NC, et al. Copper source determines chemistry and topography of implant coatings to optimally couple cellular responses and antibacterial activity. Materials Science and Engineering: C. 2021;112550.^,8484. Rokosz K, Hryniewicz T, Kacalak W, Tandecka K, Raaen S, Gaiaschi S, et al. Phosphate Coatings Enriched with Copper on Titanium Substrate Fabricated Via DC-PEO Process. Materials. 2020;13:1295.. Nevertheless, the success of each implant surface is beyond the deposition process of antimicrobials.

Figure 3
The network analysis about the most common functional compounds incorporated onto Ti surface using different deposition methods in preclinical studies. Green nodes represent the chemical deposition methods and purple nodes the physical deposition methods. The size of the node is proportional to the number of animal studies included. Gray lines represent the direct comparisons of each antimicrobial deposition method, and the line thickness is directly proportional to the number of incorporations. [ Abbreviations: AMP = antimicrobial peptides; BP = biopolymers; VitE = Vitamin E; DTM = Daptomycin; CHX = Chlorhexidine; NO = nitric oxide; CT = catechol; CFX = Ciprofloxacin; CHT = Chitosan; F = Fluoride ion; Ga = Gallium ion; HA = Hydroxyapatite; MoS2 = Molybdenum disulfide; Bi2S3 = Bismuth sulfide; Se = Sellenium ion; GTM = Gentamycin; TBM = Tobramycin; TaO = Tantalum oxide; P = Red Phosphorus; VCM = Vancomycin; Zn = Zinc ion; I = Iodine ion; Ag = Silver ion; and TiO2 = Titanium dioxide]. Reprinted from Costa et al. 2021 [27]; Copyright ⁽2021⁾; with permission from Elsevier (License number: 5214900523221).

Considering that implant-related infections are chronic conditions associated with continuous pathogenic and multi-resistant biofilm accumulation ¹¹11. Daubert DM, Weinstein BF. Biofilm as a risk factor in implant treatment. Periodontology 2000. 2019;81:29-40., the loaded surface must be stable in the oral conditions, present a long-term and sustained antimicrobial release that could cover both early and late-onset of infection, ideally with the possibility to be reloaded, when needed, to maintain an adequate therapeutic effect in clinical conditions ⁶⁴64. Haque M, Sartelli M, McKimm J, Abu Bakar M. Health care-associated infections - an overview. Infect Drug Resist. 2018;11:2321-2333.. This colossal challenge can explain the reason why only a few developed antimicrobial surfaces are progressing into clinical research. Our recent systematic review ²⁷27. Costa RC, Nagay BE, Bertolini M, Costa-Oliveira BE, Sampaio AA, Retamal-Valdes B, et al. Fitting pieces into the puzzle: The impact of titanium-based dental implant surface modifications on bacterial accumulation and polymicrobial infections. Advances in Colloid and Interface Science. 2021;298:102551. showed that only chlorhexidine ⁸⁵85. Carinci F, Lauritano D, Bignozzi CA, Pazzi D, Candotto V, Santos de Oliveira P, et al. A New Strategy Against Peri-Implantitis: Antibacterial Internal Coating. Int J Mol Sci. 2019;20(16)., silver (Ag) ions ⁸⁶86. Odatsu T, Kuroshima S, Sato M, Takase K, Valanezhad A, Naito M, et al. Antibacterial Properties of Nano-Ag Coating on Healing Abutment: An In Vitro and Clinical Study. Antibiotics (Basel). 2020;9(6)., and titanium dioxide (TiO₂) ⁸⁷87. Cucchi A, Molè F, Rinaldi L, Marchetti C, Corinaldesi G. The Efficacy of an Anatase-Coated Collar Surface in Inhibiting the Bacterial Colonization of Oral Implants: A Pilot Prospective Study in Humans. Int J Oral Maxillofac Implants. 2018;33:395-404. antimicrobial coatings for dental implants have been tested in clinical trials, showing a limited effect on long term infection control. Thus, most of the proposed surfaces with good preclinical results are hardly scalable and could significantly raise the price of implants, with as-yet-unknown dental clinical benefits.

Smart implant surfaces

Based on the current limitations related to the short-term effect of antimicrobial-loaded surfaces, smart surfaces engineering is growing as a novel generation of antimicrobial approaches for implant applications ⁸⁸88. Adlhart C, Verran J, Azevedo NF, Olmez H, Keinänen-Toivola MM, Gouveia I, et al. Surface modifications for antimicrobial effects in the healthcare setting: a critical overview. Journal of Hospital Infection. 2018;99:239-249.. Theoretically, smart surfaces are bio responsive materials that respond to 'on-demand' internal/external stimuli to start the antimicrobial agent release only when infections are present. This strategy can provide ideal antimicrobial concentrations at the precise moment and local of the infection, thus diminishing toxicity and microbial resistance. Some external (e.g., ultrasound, temperature, light, magnetic field, and electrical pulses) and internal (e.g., potential redox, enzymatic activity, O₂ level, and pH) stimulus have been tested in biomedical applications to activate this developed smart surfaces, showing to be a reliable drug delivery strategy with reusability property to guarantee the activation of the surface several times, as needed. Furthermore, to enhance the optimization of these surfaces, dual-stimulus approaches have been recently proposed to faster both prevention and clinical treatment stages of dental ⁸⁹89. Nagay BE, Dini C, Cordeiro JM, Ricomini-Filho AP, de Avila ED, Rangel EC, et al. Visible-Light-Induced Photocatalytic and Antibacterial Activity of TiO2 Codoped with Nitrogen and Bismuth: New Perspectives to Control Implant-Biofilm-Related Diseases. ACS Appl Mater Interfaces. 2019;11:18186-202. and orthopedic ²⁴24. Hong L, Liu X, Tan L, Cui Z, Yang X, Liang Y, et al. Rapid Biofilm Elimination on Bone Implants Using Near-Infrared-Activated Inorganic Semiconductor Heterostructures. Advanced Healthcare Materials. 2019;8:1900835. infections. In a nutshell, smart implant surfaces engineering is a relatively new area and highly promising, but has yet to be studied thoroughly and systematically for dental implants therapy in the near future.

Final remarks, challenges, and future perspectives

A significant concern emerging from current Implant Dentistry is the increased prevalence of peri-implant infections and the lack of consensus on the most effective therapeutic technique to treat such diseases. Often, diseased implants need to be removed, damaging bone and supporting tissues and creating a bigger problem to be solved prior the possibility of new implant placement ⁹⁰90. Roy M, Loutan L, Garavaglia G, Hashim D. Removal of osseointegrated dental implants: a systematic review of explantation techniques. Clin Oral Investig. 2020;24:47-60.. To overcome this issue, new strategies for peri-implant biofilm control are urged to be developed, targeting the long-term predictability of the implant treatment. In this regard, emerging surface modifications with antimicrobial and/or antifouling properties have gained a burst of attention, which motivated us in this review to reflect what is currently available and what are the future directions in this field.

There is no doubt that the first developed antimicrobial surfaces associated with the incorporation of bioactive elements or antimicrobial drugs have frustrated us to some extent. Such surfaces work in the principle of contact-killing or drug release ⁸⁴84. Rokosz K, Hryniewicz T, Kacalak W, Tandecka K, Raaen S, Gaiaschi S, et al. Phosphate Coatings Enriched with Copper on Titanium Substrate Fabricated Via DC-PEO Process. Materials. 2020;13:1295.^,9191. Jennings JA, Beenken KE, Skinner RA, Meeker DG, Smeltzer MS, Haggard WO, et al. Antibiotic-loaded phosphatidylcholine inhibits staphylococcal bone infection. World J Orthop. 2016;7:467-474., but their antimicrobial effect is not sustainable to match the chronic process of peri-implant infections. To worsen the scenario, up to now, there has been no success in creating a surface able to be reloaded with a fresh antimicrobial agent to replace the released one on dental implants surfaces, partially because of the difficulty of access to these sites. Importantly, the burst and uncontrolled release of drugs can have an impact on the development of bacteria-resistant strains and can load to cytotoxicity to surrounding host cells. We also face many studies using non-reliable in vitro and in vivo models that fail to mimic the oral environment, the human microbiota, and the complex nature of the disease. No wonder these surfaces have not been extensively tested in randomized controlled clinical trials nor gained the implant market, even though it might be a turning point to fight such disease.

Currently, in an interdisciplinary and multifaceted approach, researchers have dedicated their efforts to developing the so-called smart/intelligent surfaces. Those surfaces respond to certain stimuli to release the antimicrobial agent when precisely needed, in a site-specific manner. However, considering that the peri-implant disease has an immune-inflammatory nature, just controlling the biofilm is not enough and there is a need to incorporate immunomodulatory agents with anti-inflammatory properties to control the host response as well ⁹²92. Albrektsson T, Dahlin C, Reinedahl D, Tengvall P, Trindade R, Wennerberg A. An Imbalance of the Immune System Instead of a Disease Behind Marginal Bone Loss Around Oral Implants: Position Paper. Int J Oral Maxillofac Implants. 2020;35:495-502.^,9393. Li Y, Ling J, Jiang Q. Inflammasomes in Alveolar Bone Loss. Front Immunol. 2021;12:691013.. This should definitely be considered when these so called smart surfaces are advanced enough, so that they can also modulate the exacerbated host defense, often responsible for tissue destruction ⁹²92. Albrektsson T, Dahlin C, Reinedahl D, Tengvall P, Trindade R, Wennerberg A. An Imbalance of the Immune System Instead of a Disease Behind Marginal Bone Loss Around Oral Implants: Position Paper. Int J Oral Maxillofac Implants. 2020;35:495-502.^,9393. Li Y, Ling J, Jiang Q. Inflammasomes in Alveolar Bone Loss. Front Immunol. 2021;12:691013.. Interesting, there is emerging evidence showing an important role of the host immune modulation when implants present bone loss around them, as they can be seen as foreign bodies that elicit a foreign body response after placed in contact with bone tissue ⁹²92. Albrektsson T, Dahlin C, Reinedahl D, Tengvall P, Trindade R, Wennerberg A. An Imbalance of the Immune System Instead of a Disease Behind Marginal Bone Loss Around Oral Implants: Position Paper. Int J Oral Maxillofac Implants. 2020;35:495-502.^,9494. Albrektsson T, Jemt T, Mölne J, Tengvall P, Wennerberg A. On inflammation-immunological balance theory-A critical apprehension of disease concepts around implants: Mucositis and marginal bone loss may represent normal conditions and not necessarily a state of disease. Clin Implant Dent Relat Res.2019;21:183-189.. Similar reactions, including chronic inflammation, can also be seen in the interface of orthopedic implants even though they are not always exposed to bacteria, leading to aseptic loosening, often linked to a reactivation of the inflammatory-immune system ⁹⁵95. Alrabeah GO, Brett P, Knowles JC, Petridis H. The effect of metal ions released from different dental implant-abutment couples on osteoblast function and secretion of bone resorbing mediators. J Dent. 2017;66:91-101..

Recent evidence is accumulating and suggesting that the presence of Ti products around dental implants may contribute to microbial dysbiosis and peri-implantitis ⁹⁶96. Souza JGS, Costa Oliveira BE, Bertolini M, Lima CV, Retamal-Valdes B, de Faveri M, et al. Titanium particles and ions favor dysbiosis in oral biofilms. J Periodont Res.55:258-266. 2020, and even in aseptic conditions (without the presence of microbial biofilm) Ti products released from the surface may result in damage to host tissues by negatively impacting on cell homeostasis, increasing inflammatory reaction in the surrounding tissues, bone loss, and implant detachment ⁹⁷97. Zhou Z, Shi Q, Wang J, Chen X, Hao Y, Zhang Y, et al. The unfavorable role of titanium particles released from dental implants. Nanotheranostics. 2021;5:321-332.. Thus, blocking both the inflammation and osteoclastogenesis locally by means of a slow-release Ti surface treatment could be an interesting option for host modulation in order to prevent bone loss around implants ⁹⁸98. Eger M, Hiram-Bab S, Liron T, Sterer N, Carmi Y, Kohavi D, et al. Mechanism and Prevention of Titanium Particle-Induced Inflammation and Osteolysis. Front Immunol. 2018;9:2963.. Although it has not been experimentally tested yet, this could be a promising therapeutic approach for the clinical management of peri-implant bone loss. Importantly, regardless of how these new surfaces are developed, it is important to consider their stability in the oral environment to avoid leaching of Ti particles and degradation products to be released in oral and nonoral tissues, further exacerbating the inflammatory process.

Another field of investigation with promising outcomes is the nature-inspired surfaces to provide antifouling activity under safe conditions ⁷¹71. Linklater DP, Baulin VA, Juodkazis S, Crawford RJ, Stoodley P, Ivanova EP. Mechano-bactericidal actions of nanostructured surfaces. Nat Rev Microbiol. 2021;19:8-22.. There is a wide variety of surfaces topographies to explore dedicated to the micro and nano world that interact with the bacteria in different ways. However, it is noticeable that those surfaces may also reflect on the human cell behavior; therefore, an equilibrium in the antifouling property is essential to be reached in order to maintain the surface’s in vivo compatibility. In this regard, machine-learning algorithms to engineer reliable surfaces are in-hand strategies to better explore novel surfaces architecture ⁹⁹99. Vermeulen S, Honig F, Vasilevich A, Roumans N, Romero M, Dede Eren A, et al. Expanding Biomaterial Surface Topographical Design Space through Natural Surface Reproduction. Advanced Materials. 2021;33:2102084..

Finally, to smartly win the never-ending war against polymicrobial infections on dental implants and gain potential breakthroughs in the surface-engineering implant field is important to deeply recognize the strategies of our enemy, understand the precise mechanism of etiopathogeneses, and the risk factors of the peri-implant disease. Will we win the war? We do not know precisely, but significant knowledge is still to be explored by well-designed studies.

Acknowledgments

This study was funded by São Paulo Research Foundation (FAPESP) grant number 2020/10436-4 and Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (Grant/Award Number: 001) to R.C.C., and Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq) grant number 304853/2018-6 and São Paulo Research Foundation (FAPESP)grant number 2020/05231-4to V.A.R.B.

References

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