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Review Article
Jahnavi Madaan*,1, P.S. Manoharan2, Sai Kiran Koppolu3,

1Jahnavi Madaan, First Year postgraduate, Department of Prosthodontics, Indira Gandhi Institute of Dental Sciences, Sri Balaji Vidyapeeth University, Pondicherry.

2Department of Prosthodontics, Indira Gandhi Institute of Dental Sciences, Sri Balaji Vidyapeeth University, Pondicherry

3Department of Prosthodontics, Indira Gandhi Institute of Dental Sciences, Sri Balaji Vidyapeeth University, Pondicherry

*Corresponding Author:

Jahnavi Madaan, First Year postgraduate, Department of Prosthodontics, Indira Gandhi Institute of Dental Sciences, Sri Balaji Vidyapeeth University, Pondicherry., Email: jahnavi.libran@gmail.com
Received Date: 2022-06-19,
Accepted Date: 2022-08-12,
Published Date: 2022-12-31
Year: 2022, Volume: 14, Issue: 4, Page no. 8-18, DOI: 10.26463/rjds.14_4_20
Views: 920, Downloads: 41
Licensing Information:
CC BY NC 4.0 ICON
This work is licensed under a Creative Commons Attribution-NonCommercial 4.0.
Abstract

Graphene and graphene-based nanomaterials have recently gained interest in nanomedicine as well as in dentistry. They have excellent mechanical, electrical, and thermal properties. This review discusses various applications of graphene and its derivatives in the field of dentistry including denture base materials, restorative materials, implants, bone regeneration, and oral cancer

<p>Graphene and graphene-based nanomaterials have recently gained interest in nanomedicine as well as in dentistry. They have excellent mechanical, electrical, and thermal properties. This review discusses various applications of graphene and its derivatives in the field of dentistry including denture base materials, restorative materials, implants, bone regeneration, and oral cancer</p>
Keywords
Graphene, Nanoparticles, Reduced graphene oxide, Polymethylmethacrylate, Implant
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Introduction

The scientific world is transforming with the discovery of new materials; nanoforms are taking the rule nowadays. Graphene has emerged as a novel and potential nanoparticle that has exceptional properties. It is unique in being the thinnest and strongest material in existence. It is composed of two-dimensional sheets of less than 10mm thickness.1 Graphene has various applications in varied fields. It is used in supercapacitors, wireless powers, energy storage, and nanoscale transistors for water filtration and desalination. In the biomedical field, it is used in DNA detection, drug delivery, detection of bacteria, cancer therapy,2 biosensing and bioimaging, photothermal therapy 3, and in dentistry.

Graphene was discovered by Andre Geim and Konstantin Novoselov at the University of Manchester in 2004.2 Graphene is produced by mechanical or chemical exfoliation of graphite via chemical vapor deposition. It is considered hydrophobic because of the absence of oxygen groups.4

Graphene-related materials can be classified either on the number of layers (eg. mono- or multi-layered) or their chemical modification into:

1. Graphene oxide (Figure 1) (GO)

2. Reduced graphene oxide (rGO)

3. Nitrogen-doped graphene (N-G)

The various forms of graphene are:

a) Graphene nanoplates

b) Graphene nanoflakes

c) Graphene powder

d) Graphene thin sheets

e) Graphene foam2

In this paper, the applications of graphene as a reinforcement material in dentistr1y and its properties as a novel nanomaterial are mentioned.

Graphene in denture base materials

Polymethylmethacrylate (PMMA) is one of the most commonly used denture base materials.5 There are certain drawbacks of this material for which nanoparticles have been incorporated to enhance those properties. These are:

  • Mechanical properties
  • Antimicrobial property
  • Thermal and electrical properties6

A variety of reinforcing agents in the form of cobalt-chromium wires, metallic wires, polyamide fibers, carbon fibers, ultra-high molecular weight polyethylene, and varying amounts of powdered silver, copper, aluminum, and ceramic fillers have been added previously to PMMA.7

Recently, graphene has emerged as a potentially useful nanofiller that is gaining research interest due to its exceptional properties. Various studies have been conducted to test the properties of PMMA after the incorporation of graphene (Table 1).

Thus the experiments suggest that GO incorporated PMMA significantly improved the mechanical and thermal properties of PMMA and also has antimicrobial and anti-adhesion characteristics.6 Graphene oxide (GO) has proven to be an anti-quorum sensing agent which is why it is an effective anti-biofilm addition to PMMA.12

Research is needed to further evaluate the bonding of teeth with GO/PMMA resin dentures, the effect on impact strength after GO incorporation, and the intraoral evaluation of the anti-biofilm effect.

Graphene in restorative materials:

Restorative cement, crowns, and endodontic materials have been reinforced with various materials over the years to improve their properties.. Antibiotics, quaternary ammonium compounds, and chlorhexidine have been used as reinforcing agents in glass ionomer cement or zirconia and alumina in bioactive cements to improve certain mechanical properties.. Graphene being an exceptional nanofiller has recently gained importance to be incorporated into these materials without compromising the overall performance of the material(Table 2).13,14  

Graphene in tissue engineering

Bone regeneration plays an important part in regenerative dentistry. Human dental pulp stem cells (hDPSCs) are used for tissue engineering as they secrete a dentin matrix and have the capability to differentiate into odontoblasts.21 Recently, bioactive glass (BAG) has been used as a biomaterial for dentin regeneration due to its capability of releasing ions and resorbable properties. But BAG lacks adequate mechanical strength and is not sufficient for heavily loaded environments. Bioactive ceramics such as mesoporous bioactive glass nanoparticles (MBNs) have weak mechanical properties, are highly brittle, and have low tensile strength. Certain polymers and inorganic materials have been found as reinforcement materials to enhance the mechanical strength of these materials.

The incorporation of graphene into these was done in a few in vitro studies. It was found that graphene increased the proliferation of human mesenchymal stem cells (MSCs) and there was no sign of cytotoxicity.22 Graphene can also be incorporated into membranes for guided bone regeneration (GBR) done in dentistry. The role of graphene in driving the osteogenic differentiation of stem cells has been evaluated through many studies as mentioned in Table 3.

Graphene has been used recently in tissue engineering field to enhance and improve the biocompatibility, spacemaking, clinical manageability, and tissue integration of the various membranes and grafts used.22

Graphene in esthetic dentistry

Teeth whitening is a procedure that has gained importance recently. It is done using hydrogen peroxide (H2O2 ) based materials. The risk factors of tooth whitening are dentin sensitivity, gingival irritation, and changes in tooth microstructure which depend on the concentration of H2O2 and the duration of the treatment.

Su and co-workers experimented with rGO and cobalt tetraphenylporphyrin (CoTPP) as catalysts for tooth bleaching to overcome these risks. It was found that H2O2 plus rGO/ CoTPP under photoactivation increased the whitening effect of peroxide and decreased the treatment time further decreasing the risks involved in the treatment.22

Graphene as antibacterial and anti-demineralization material

Demineralization of dentin is an irreversible loss of tooth structure which further leads to pain and hypersensitivity. Many agents have been used to treat the demineralization of dentin such as fluoride and oxalate-based materials. The major drawback of these is that they cause discoloration of dentin.

Graphene as an anti-demineralization agent:

Graphene oxide has been tested to evaluate its potential to prevent the demineralization of dentin by covering its surface and sealing the orifices of the dentinal tubules. GO along with 5 different f-GO-nanocomposites were synthesized in a study done by Nizami et al. (2019) and its effect on the prevention of demineralization of dentin was seen. It was found that f-GO-nanocomposites were stronger against demineralization than other agents used before and led to lesser or no color change of dentin, proving it to be a better material. Hence, f-GO-nanocomposites were suitable for the prevention of tooth decalcification caused by cariogenic microbes.23 

Graphene as an antibacterial agent:

Hu et al. were the first to discover the bactericidal effect of graphene-based materials against Escherichia coli. The activity of graphene against Streptococcus mutans in both planktonic and biofilm forms was evaluated by Zhao et al. (2020). In the study, it was found that GO nanosheets had an antibacterial effect on S.mutans in both forms in a concentration-dependent manner. Their antibacterial activity was through oxidative stress damage. Thus, GO could be a potential additive in dental restorative materials preventing the adhesion of bacteria.24

He et al. mentioned that GO had a strong antibacterial effect on dental pathogens including S.mutans. He evaluated the effect of GO nanosheets against S.mutans, Porphyromonas gingivalis and Fusobacterium nucleatum . 25

So, the antibacterial effect of GO is prominent and with increasing concentration, it has a more enhanced effect on suppressing the viability of pathogens. But the effect of GO could be altered by some factors like saliva, electrolytes, and proteins. So, further studies are needed to have a better understanding of the properties of GO in preventing caries.

Graphene in dental implants

Dental implants are made with various surface modifications to enhance osseointegration and suppress biofilm formation to prevent peri-implantitis. Recently, graphene has been used for coating titanium implants to evaluate its benefit in osseointegration and as an antibacterial agent. Various studies that have been undertaken are mentioned in Table 4.

Various types of graphene including GO and rGO have been proven to have greater diffusion and stability and their potential to be used as a coating for implants is also prominent. But further in vivo research and evidence are required for graphene to be used as a promising material in implantology.23

Graphene in oral cancer treatment

It is important to check the risk factors of oral cancer and get it diagnosed at the earliest to help prevent its spread. Resistance to conventional therapeutic approaches by cancer stem cells (CSCs) or tumor stimulating cells has been observed. Various studies have suggested that GO can be delivered as a therapeutic agent for targeting CSCs at the location of the tumor. GO has an inhibiting effect on signal transduction pathways.2

Various studies have been done to evaluate graphene for cancer therapy. They are enlisted in Table 5.12

Limitations, scope, and future perspectives

Graphene is in its early stage of research and a few challenges are still there which need to be addressed before it is widely commercialized as a dental material. Several reports have mentioned that the behavior of graphene and its derivatives and their toxicity depends on the physiochemical properties of the structure.1 One of the major goals for the biomedical application of graphene as an antibiotic agent is based on the understanding of its toxicity profile. We must investigate the cost-effectiveness, reproducible synthesis, and stability of these nanomaterials for use in dentistry. Graphene-based nanomaterials (GBNs) must undergo more clinical trials to check their safety and efficacy of them, which will further dictate their use in this field.1

As graphene is still in its infancy stage, there is a need for proper future research to change the material into a market-oriented research area. However, it provides great avenues for further development in the applications of graphene.4

Conflict of interest

None

 

Supporting File
References
  1. Tahriri M, Del Monico M, Moghanian A, et al. Graphene and its derivatives: Opportunities and challenges in dentistry. Mater. Sci. Eng. C 2019;102:171-85.
  2. Lakshmi KA, llsha Rao G, Arthiseethalakshmi S, et al. The revolutionary era of Graphene in Dentistry-a review. RJMS 2016; 6(4):139-45. 
  3. Priyadarsini S, Mohanty S, Mukherjee S, et al. Graphene and graphene oxide as nanomaterials for medicine and biology application. J. nanostructure chem. 2018 ;8(2):123-37. 
  4. Dasari Shareena TP, McShan D, Dasmahapatra AK, et al. A review on graphene-based nanomaterials in biomedical applications and risks in environment and health. Nanomicro Lett 2018 ;10(3):1-34. 
  5. Di Carlo S, De Angelis F, Brauner E, et al. Flexural strength and elastic modulus evaluation of structures made by conventional PMMA and PMMA reinforced with graphene. Eur Rev Med Pharmacol Sci. 2020; 24(10):5201-8.
  6. Lee JH, Jo JK, Kim DA, et al. Nano-graphene oxide incorporated into PMMA resin to prevent microbial adhesion. Dent Mater 2018 ;34(4):e63-72. 
  7. Khan AA, Mirza EH, Mohamed BA, et al. Physical, mechanical, chemical and thermal properties of nanoscale graphene oxide-poly methylmethacrylate composites J Compos Mater 2018 ;52(20):2803- 13. 
  8. Alamgir M, Nayak GC, Mallick A, et al. Processing of PMMA nanocomposites containing biocompatible GO and TiO2 nanoparticles. Mater. Manuf. Process 2018 ;33(12):1291-8.
  9. Yang J, Yan X, Wu M, et al. Self-assembly between graphene sheets and cationic poly (methyl methacrylate)(PMMA) particles: preparation and characterization of PMMA/graphene composites. J Nanopart Res 2012 ;14(1):1-9.
  10. Song J, Zhang J, Lin C. Influence of graphene oxide on the tribological and electrical properties of PMMA composites. J. Nanomater 2013 ;2013. 
  11. Ramanathan T, Abdala AA, Stankovich S, Dikin DA, et al. Functionalized graphene sheets for polymer nanocomposites. Nat. Nanotechnol. 2008; 3(6):327-31. 
  12. Nizami MZI, Takashiba S, Nishina Y. Graphene oxide: A new direction in dentistry. Appl Mater Today 2020;19:100576 
  13. Chen J, Zhao Q, Peng J, et al. Antibacterial and mechanical properties of reduced graphene-silver nanoparticle nanocomposite modified glass ionomer cements. J Dent 2020 ;96:103332.
  14. Dubey N, Rajan SS, Bello YD, et al. Graphene nanosheets to improve physico-mechanical properties of bioactive calcium silicate cements. Mater 2017 ;10(6):606.
  15. Malik S, Ruddock FM, Dowling AH, et al. Graphene composites with dental and biomedical applicability. Beilstein J. Nanotechnol 2018 ;9(1):801-8.
  16. Lv S, Ting S, Liu J, et al. Use of graphene oxide nanosheets to regulate the microstructure of hardened cement paste to increase its strength and toughness. Cryst Eng Comm. 2014;16(36):8508- 16. 
  17. Mehrali M, Moghaddam E, Seyed Shirazi SF, et al. Mechanical and in vitro biological performance of graphene nanoplatelets reinforced calcium silicate composite. PLoS One. 2014 ;9(9):e106802. 
  18. Sava S, Moldovan M, Sarosi C, et al. Effects of graphene addition on the mechanical properties of composites for dental restoration. Mater. Plast 2015;52(1):90-2 
  19. Walker LS, Marotto VR, Rafiee MA, et al. Toughening in graphene ceramic composites. ACS nano 2011 ;5(4):3182-90. 
  20. Liu J, Yan H, Reece MJ, et al. Toughening of zirconia/alumina composites by the addition of graphene platelets. J. Eur. Ceram. Soc 2012 ;32(16):4185-93.
  21. Ahn JH, Kim IR, Kim Y, et al. The effect of mesoporous bioactive glass nanoparticles/graphene oxide composites on the differentiation and mineralization of human dental pulp stem cells. Nanomaterials 2020 ;10(4):620. 
  22. Guazzo R, Gardin C, Bellin G, et al. Graphene-based nanomaterials for tissue engineering in the dental field. Nanomaterials 2018 ;8(5):349. 
  23. Nizami MZ, Nishina Y, Yamamoto T, et al. Functionalized graphene oxide shields tooth dentin from decalcification. J. Dent. Res 2020 ;99(2):182- 8.
  24. Zhao M, Shan T, Wu Q, et al. The antibacterial effect of graphene oxide on Streptococcus mutans. J. Nanosci. Nanotechnol 2020 ;20(4):2095-103. 
  25. He J, Zhu X, Qi Z, et al. Killing dental pathogens using antibacterial graphene oxide. ACS Appl. Mater. Interfaces 2015 ;7(9):5605-11. 
  26. Kulshrestha S, Khan S, Meena R, Singh BR, et al. A graphene/zinc oxide nanocomposite film protects dental implant surfaces against cariogenic Streptococcus mutans. Biofouling 2014 ;30(10):1281-94. 
  27. Park S, Kim H, Choi KS, et al. Graphene– Chitosan Hybrid Dental Implants with Enhanced Antibacterial and Cell-Proliferation Properties. Appl. Sci 2020;10(14):4888. 
  28. Zhang C, Jiang Z, Zhao L, et al. Synthesis and characterization of multilayer graphene oxide on yttria-zirconia ceramics for dental implant. J Mater Res 2020 ;35(18):2466-77.
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