International Journal of Engineering Materials and Manufacture (2021) 6(4) 225-241 

https://doi.org/10.26776/ijemm.06.04.2021.01 

Eisenstat, J. A.
1
, Gotthardt, D. A.

1
, Assor, R.

1
, Dempsey L. R.

1
 and Hasan, M. H.

2  
1
Department of Electrical, Computer, and Biomedical Engineering 

2
Department of Mechanical and Industrial Engineering 

Ryerson University, Canada 

E-mail: hasibulhasan@ryerson.ca 

 

Reference: Eisenstat et al. (2021). A Comparative Review of Material Properties for Current and Future Dental Filling Nanomaterials. 

International Journal of Engineering Materials and Manufacture, 6(4), 225-241. 

 

 

A Comparative Review of Material Properties for Current and Future 

Dental Filling Nanomaterials 

 

 

Joshua A. Eisenstat, Dennis A. Gotthardt, Rebecca Assor, Liam R. Dempsey and Muhammad H. 

Hasan 

 

 

Received: 10 February 2021 

Accepted: 20 April 2021 

Published: 01 October 2021 

Publisher: Deer Hill Publications 

© 2021 The Author(s) 

Creative Commons: CC BY 4.0 

 

 

ABSTRACT 

Nanomaterials observe specialized properties relative to gross materials. Due to their small size, specialized 

nanomaterial properties include decreased reactivity, an increased surface area to volume ratio, heightened structural 

properties, and in some cases, antimicrobial and antibacterial effects. Current researchers are looking to use 

nanoparticle/nanomaterial properties to solve prevalent dental issues that cannot be addressed with traditionally 

used materials. This paper serves as an extensive review of current nanomaterial applications as they pertain to dental 

fillings and dental filling processes. Comparative assessments of traditional materials used in dental fillings were made, 

as well as comparative assessments of currently used nanomaterials in dental fillings. Material comparisons are based 

on criteria pertaining to biocompatibility, toxicity, reactivity, cost, and antimicrobial/antibacterial properties. When 

comparing the three most currently used dental filling nanomaterials – Carbon-Based Nanotubes, Silica Nanoparticles 

and Silver-Coated Nanoparticles – it was observed that Silica Nanoparticles demonstrated the greatest material 

advantage and should be recommended for continued use. Issues regarding future developmental dental filling 

applications of graphene nanoparticles, starch nanoparticles, organic nanoparticles and gold nanoparticles were also 

reviewed. 

Keywords: Nanomaterials, antibacterial, dental fillings, silica resins, biocompatibility. 

 

1 INTRODUCTION 

Strong emphasis is placed on oral hygiene and dental appearance in western society. This is evident when observing 

the financial capital designated towards dental care in western countries. In 2015, Canada spent 12.7 billion dollars 

on dental care [1]. Comparatively, the United States of America spent 124 billion dollars on dental care [2]. 

The current spectrum of dental procedures ranges from physical repairs - dental fillings, root canals - to cosmetic 

procedures, such as teeth whitening. The World Health Organization reported that roughly 60-90 percent of children 

and about 100 percent of adults worldwide have experienced cavities [3]. As a result, dental fillings are the most 

performed dental procedures [4]. Traditional dental filling materials include amalgam, glass ionomers, resin ionomers, 

resin composites as well as gold and nickel alloys [5]. Among traditional dental filling materials, each observes distinct 

advantages and disadvantages. Since some materials have better properties than others - life expectancy, toxicity, 

corrosion, etc.- it is often difficult to find the optimal dental filling material [5]. Faced with complications associated 

with traditional dental filling materials, researchers are looking to nanomaterials for solutions. 

Nanomaterials are composed of nanometer sized particles. Due to the small particle size, nanomaterials often 

exhibit special physical and chemical properties not observed in gross materials [5]. Due to the special properties of 

nanomaterials, extensive research has been conducted looking into the advantages and disadvantages of using 

nanomaterials for medical and dental applications [6]. This paper will provide a comprehensive review of the current 

methods for using nanomaterials in dental fillings, an in-depth comparison of those current methods - highlighting 

advantages and disadvantages, as well as look into future developments regarding the applications of nanomaterials 

in dental fillings. 

  



Eisenstat et al. (2021): International Journal of Engineering Materials and Manufacture, 6(4), 225-241 

226 

2 TRADITIONAL DENTAL FILLINGS – AN OVERVIEW  

A variety of traditional materials are used for dental filling procedures. Traditionally used dental filling materials 

include dental amalgams, resin ionomers, composite resins and glass ionomers. Dental filling material selection is 

based on properties including viscosity, moldability and the ideal marginal integrity of the dental filling in the tooth 

[7]. Dental fillings are also chosen based on susceptibility to corrosion from pH, temperature, protein, saliva, oral 

health conditions, and diet [8]. Saliva, for example, has a pH range of 5.2 to 7.8.  Food consumption and diet must 

also be taken into consideration during dental filling material selection. The more acidic the food is, the more likely 

corrosion will occur to dental fillings and teeth [8]. Among traditionally used dental filling materials, there is not one 

material that provides a solution to all problems. In fact, some currently used traditional dental filling materials can 

induce unintended health defects. For example, dental amalgam - a commonly used dental filling material – could 

pose health risks for patients due to its high mercury concentration [5]. Traditional dental filling materials each come 

with their respective advantages and disadvantages [5]. 

 

Table 1: Advantages and Disadvantages of Traditional Dental Fillings [5] 

 

Dental Filling Advantages Disadvantages 

Dental Amalgam 

-    Durable 

-    Inexpensive 

-    Good Corrosion Resistance 

-    Aesthetically displeasing 

-      Potential Toxic Mercury 

Content 

Resin Ionomer 

-    Aesthetically pleasing 

-    Limited Sensitivity to Temperature 

Changes 

-    Relatively Good Against Future Decay 

-    Poor Wear Resistance 

-    Expensive 

Composite 

Resins 

-    Good Strength and Toughness 

-    Aesthetically Pleasing 

-    Good Wear Resistance 

-    Varying tooth sensitivity 

-    Sensitive to temperature 

changes 

-    Expensive 

Glass Ionomers 

-    Aesthetically Pleasing 

-    Relatively Good Against Future Decay 

-    Minimal Sensitivity 

-    Poor Wear Resistance 

 

 

2.1 Nanomaterial Dental Filling Biocompatibility 

External materials can be inserted into the body only if they are biocompatible with live tissue. Nanomaterials are 

said to be biocompatible if a homogeneous composition can be made with the inserted nanomaterial and biological 

tissue. Homogeneous nanomaterials demonstrate satisfactory biocompatibility in the patient’s oral cavity relative to 

heterogeneous nanomaterial compositions [9]. If the added nanomaterials observe high levels of reactivity with the 

inorganic dental filling material, it is an indication of a homogeneous composition. High levels of nanoparticle 

reactivity with dental fillings are observed to be beneficial [9]. However, if the added nanomaterials have a high 

level of reactivity with soft tissue in the oral cavity - gums, enamel, tongue - then the biocompatibility of the dental 

filling is deemed unsatisfactory, and the nanoparticle’s high level of reactivity becomes problematic [9]. Material 

reactivity is determined by quantifying the relationship of the surface area relative to the given volume ratio of the 

particles [10]. This relationship can be described using the following equations 1-3 [10]. As the radius of a particle 

decreases, reactivity of the particle increases, as illustrated in the mathematical principles in equation 3. Due to the 

small radius of nanoparticles, chemical reactivity increases gradually. Nanomaterial toxicity is a result of their small 

particle size. Smaller particle size allows for easier passage through different body membranes [11]. 

 

𝑆𝑢𝑟𝑓𝑎𝑐𝑒 𝐴𝑟𝑒𝑎 = 4𝜋𝑟2          (1) 
 

𝑉𝑜𝑙𝑢𝑚𝑒 =
4

3
𝜋𝑟3       (2) 
 

𝑅𝑒𝑎𝑐𝑡𝑖𝑣𝑖𝑡𝑦 =
𝑆𝑢𝑟𝑓𝑎𝑐𝑒 𝐴𝑟𝑒𝑎

𝑉𝑜𝑙𝑢𝑚𝑒
=

4𝜋𝑟2

4

3
𝜋𝑟3

=
3

𝑟
     (3) 

  



A Comparative Review of Material Properties for Current and Future Dental Filling Nanomaterials 

227 

3 CURRENT AND PREVIOUSLY CONDUCTED DENTAL FILLING NANOMATERIAL RESEARCH  

3.1 Polymethyl Methacrylate (PMMA) 

The most common material used in dental fillings today are composite resin fillings [12]. This is due to the visual 

similarity of the resin material and dental tissue. Current research has developed a nanomaterial composite resin filler 

as an alternative to traditionally used composite resin fillers. Polymethyl methacrylate (PMMA) is a nanocomposite 

resin filling that has been observed to be a more effective resin filler than current composite resin filler variants. 

Experimental trials determined that a 5% volume fraction of 40% Titania (𝑇𝑖𝑂2), and 60% Calcium Aluminate 
(𝐶𝑎𝐴𝑙2𝑂4) nanoparticles presented the longest life, best surface interactions (tribological characteristics), and the most 
stable nano-composition supported by nanoparticles [12]. Under experimental trials, PMMA has exhibited satisfactory 

cytotoxicity metrics by demonstrating low damage to erythrocytes and even promoting cellular activity [13]. 

Additionally, PMMA has seen expanded use cases regarding denture efficacy and applicability. When compared to 

other artificial materials PMMA has demonstrated a harder enamel surface replacement and increased wear resistance 

[14]. 

 

3.2 Nanomaterial Composite Resins 

Research has been done to create new nanoparticle composite resins [15]. Composite resins are a type of restorative 

material [15]. Examples being strengthening agents like mineral filler particles [15]. These materials can be dispersion 

reinforced, particulate reinforced, or hybrid composites. Although these resins have high dispersion reinforcement, 

microfill resins are relatively weak structurally. This limits them only to low stress restorations [15]. The goal of this 

dental filling material was to retain high strength properties for load-bearing restorations and keep its glossy 

appearance after long periods of wear [15]. 

The dental composite is applied to the teeth and then exposed to a light source. The light source is used to cure 

the resin material. The resin is suitable for use in stress bearing applications because of its flexural strength of more 

than 100MPa [15]. Structural fillers that are suitable for this resin are barium magnesium aluminosilicate glass, barium 

aluminoborosilicate glass (BAG), amorphous silica, silica-zirconia, silica-titania, barium oxide, quartz, alumina and 

various other inorganic oxide particles [15].  The particles present have an average particle size of 0.05 μm to 0.50 
μm plus a nanofiller, which observes an average particle size of roughly 100 nm [15]. 
 

3.3 Silica Nanomaterial Resins 

Silica nanoparticles are featured prominently in various current dental filling applications. Largely due to the high 

wear resistance and strong antimicrobial and antibacterial properties [16]. Studies have demonstrated significant 

reduction in oral bacteria Escherichia. Coli and Staphylococcus aureus when placed near silica nanoparticles, 

highlighting antibacterial effectiveness against both gram-negative and gram-positive bacteria [17]. 

A common use case of silica nanoparticles is the infusion of silica nanoparticles within traditional dental filling 

materials. In one study, silica nanoparticles (OX-50) and porous diatomite particles were combined with resin to 

further determine their combined mechanical properties [18]. Silica and porous diatomite particles were added to 

dental resin at different mass ratios ranging from 60% - 75% [18]. It was observed that with the increase of the silica 

- diatomite mass composition, the mechanical properties of the resin increased. With the highest microhardness 

composite at 75% of silica - porous diatomite particles, it was determined that nanosized silica and porous diatomite 

particles have a demonstrable impact on the mechanical properties of dental resin composites [18]. 

 

3.4 Silver Coated Nanomaterials 

Optical glass fibers can be coated with silver nanoparticles. This was an alternative material for root dental fillings 

during endodontic therapy (root canal treatment) [19]. The material was used because of its mechanical and 

antibacterial properties [19]. A group of glass fiber filaments were covered with silver nanoparticles and then placed 

in a solvent of tetrahydrofuran [19]. Synthesis of the silver nanoparticles involved combining silver nitrate (𝐴𝑔𝑁𝑂3) 
and sodium borohydride (𝑁𝑎𝐵𝐻4) at a 3:1 ratio. Sodium borohydride acts as a reducing agent for silver nitrate [19]. 
After 24 hours of stirring and centrifuging, the nanoparticles were dried at room temperature and recovered. 

Mechanical properties of hardness and elastic modulus were evaluated on the surface of optical glass coated with the 

silver nanoparticles. Using the process of nanoindentation, the hardness value of 3.6±0.17 GPa and an elastic 

modulus of 78.3±2.6 GPa were determined [19]. The results can be seen in Figure 1. 

 

3.5 Metallic Nanomaterials 

The introduction of tin, copper, mercury, and silver nano powders and composite nano powders, synthesized using 

Salvia miltiorrhiza Bunge root extract, play a large role in dental filling antibacterial properties [20]. Salvia miltiorrhiza 

acts as a reducing and capping agent to improve the antibacterial property of dental fillings [20]. Metallic nanoparticle 

properties include small particle size, high surface area to volume ratio, stability, high dispersity, non-cytotoxicity, 

and biocompatibility that make them beneficial for dental fillings [20]. New and evolving pathogens must be 

considered when developing dental fillings. Failures in restorative dentistry are mostly attributed to the presence of 

oral bacteria [20]. The copper composite nano powder, Salvia miltiorrhiza root extract, and silver nano powder 

demonstrated strong antibacterial properties against the oral bacteria Streptococcus mutans and Lactobacillus 

acidophilus [20]. These two strains of bacteria are some of the most prevalent forms of bacteria in the oral cavity 



Eisenstat et al. (2021): International Journal of Engineering Materials and Manufacture, 6(4), 225-241 

228 

and are the main causes for dental caries [20]. The application of metal nano powders as alternatives for antibiotics 

and disinfectants in dental filling materials show promising experimental results [20]. 

 

 

 

 

Figure 1: SEM micrographs: (a) synthesized silver nanoparticles by chemical reduction, (b) the optic fiber without 

silver nanoparticles coated on the surface of glass fiber cores, (c) the optic fiber with silver nanoparticles coated on 

the surface of glass fiber cores [19] 

 

 

3.6 Dental Cement 

Root canals are a common surgery in dentistry. Surveys conducted by the American Association of Endodontists 

observed that 15.1 million root canal procedures were conducted in 2005 and 2006 respectively [3]. Root canals 

involve the cleaning and removal of an infected tooth nerve followed by the placing of the filling material such as 

Gutta-Percha in the canal space. As the infected nerve is removed the subsequent nerve space is filled with dental 

material to prevent infection. The most common type of filling used for root canal procedures is Gutta-Percha, a 

natural resin and thermoplastic elastomer [21,22]. Gutta-Percha is seen in three different forms. - , , or .  The form 

of Gutta-Percha is dependent on the rate of material cooling. If Gutta-Percha is cooled at less than half a degree 

Celsius per hour, then  -Gutta-Percha is formed [23]. Gutta-Percha observes biological inertness, reversibility and 

non-conductibility [23]. 

Despite many beneficial properties, there are concerns regarding the ability of Gutta-Percha’s material to properly 

secure the root canal [21]. As a result of this, many sealants have been introduced to work with the filling material. 

However, the non-polar nature of most sealants renders them incompatible with the polar regions of the oral cavity 

[21]. 

 

  



A Comparative Review of Material Properties for Current and Future Dental Filling Nanomaterials 

229 

To overcome these drawbacks, new patents for dental cement compositions have been created.  Dental cement 

is comprised of various nanoparticles; Di-calcium Silicate (𝐶𝑎2𝑆𝑖𝑂4), Tricalcium Silicate (𝐶𝑎3𝑆𝑖𝑂5), Bismuth Oxide 
(𝐵𝑖2𝑂3), Gypsum, Strontium Carbonate (𝑆𝑟𝐶𝑂3), Zeolite, Calcium Sulfate (𝐶𝑎𝑆𝑂4) Di-sodium Hydrogen Phosphate 
(𝑁𝑎2𝐻𝑃𝑂4) and Tricalcium Aluminate (𝐶𝑎3𝐴𝑙2𝑂6)[21]. Dental cement is used as root-end filling material and 
demonstrates a fast-setting time, despite saliva and blood exposure. Dental cement also hardens at temperatures 

corresponding to bodily ideals at 36.1 to 37.2 degrees Celsius [21]. An important feature of dental cement are its 

microhardness and strength which come as a result of the nanoparticles in chemical solution [21]. For example, the 

gypsum incorporated into the solution has a chemical formula of 𝐶𝑎𝑆𝑂4 • 2𝐻2𝑂 [24]. The calcium sulfate is primarily 
known as anhydrite; however, the addition of water molds the material into that of nano-gypsum, which 

demonstrates significantly higher than normal levels of microhardness [25]. Ostewalder et al. conducted an 

experiment in which the microhardness of nano-gypsum was compared to an alabaster reference which has a similar 

chemical formula 𝐶𝑎𝑆𝑂4 • 0.25𝐻2𝑂 to that of nano-gypsum at varying powder to water ratios [25]. Their findings 
demonstrated that regardless of the water to powder ratio, the nano-gypsum demonstrated a compelling increase in 

Vickers Hardness (kg/𝑚𝑚2), up to approximately 3.18 times as hard as its Alabaster reference at a water to powder 
ratio of 0.22 [25]. 

 

3.7 Gutta Percha with Nano-diamonds 

Nano-diamonds, a type of carbon-based nanoparticles, have been found to have great antibacterial effects against 

both Gram-positive and Gram-negative bacteria, as well as S. aureus, E. coli and S. mutans - typical bacteria found in 

the oral cavity [26]. Moreover, the addition of nano-diamonds into resin-based materials had improved their 

antibacterial and properties. The use of Gutta-Percha was explained previously, however, there is a new and 

improved form of Gutta-Percha with nano-diamonds incorporated into the product that is currently undergoing trials 

by the American government [26]. With this invention, root canal fillers will be more stable, stronger and protect 

against harmful bacteria more efficiently with the hopes of preventing secondary caries [27].  

 

4 CURRENT NANOMATERIAL DENTAL FILLINGS – A COMPARISON 

Based on current research, the three most currently used nanomaterials in dental fillings - carbon nanotubules, silver 

nanoparticles and silica nanoparticles - were assessed in order to determine which application is most optimal. Each 

method of nanomaterial utilization observed their own respective advantages and disadvantages [4]. 

Due to their covalent and hexagonal bonding structures, carbon nanotubules present strong mechanical 

properties. This includes high strength, low particle densities and heat stability [5]. Carbon nanotubules observe 

strong adhesive properties when applied to cementum and dentin surfaces. Unfortunately, carbon nanotubules’ 

applications in dental fillings have demonstrated cases of adverse biological reactions. Reactions have included 

inflammation of the dental filling areas due to small carbon nanotubule particles crossing over membranes [5]. Carbon 

Nanotubes have been shown to demonstrate promising outcomes when combined with composite resins. Evidence 

suggests current composite resins present problems regarding resistance to future caries in dental fillings. This means 

that in composite resin fillings there exists a high possibility for gaps to be formed between the filling and the tooth, 

termed as either outer lesions or wall lesions [28]. Depending on whether the size of the gap is small or large, either 

a micro-leak or macro-leak will ensue [28]. These gaps and leaks within the tooth filling can then harbor bacteria 

leading to secondary caries [29]. Due to the antimicrobial properties of carbon nanotubes, their infusion within 

composite resin materials disrupts bacteria formation within gaps and leaks, generating a preventative effect against 

tooth decay and development of secondary caries [29]. 

Silver nanomaterial compounds are used largely due to their antibacterial and antimicrobial properties. While 

relative toxicity of silver nanomaterials is low compared to other dental filling nanomaterials, overall biological risk 

is larger due to the severity of potential toxic effects. Silver can alter DNA base pairings; cause DNA unwinding and 

disrupt cellular phagocytosis and actin function [5]. Silver oxide nanoparticles were experimented with to determine 

if they possess antimicrobial properties against Streptococcus mutans and Lactobacillus [30]. As mentioned previously, 

these two strains of bacteria are found in oral cavity, resulting in dental caries [31,32]. It was found that composite 

resins with either silver or zinc-oxide nanoparticles added into the solution demonstrated greater antibacterial activity 

against both Streptococcus mutans and Lactobacillus [30].  

Silica nanomaterials are an inexpensive nanomaterial dental filling alternative, relative to carbon nanotubules and 

silver nanomaterials. An advantage of incorporating silica nanomaterials is the improved wear resistance that they 

provide dental fillings [6]. As a dental filling wears, particles are shed from the surface of the dental filling and the 

tooth roughens [33]. The size of the particles shed are crucial for the composition of the remaining tooth. Larger 

particle shedding can lead to poor tooth filling composition. When traditional dental fillers are used, shed tooth 

particles are larger, and the shedding of the given particles will result in a rougher filling surface [33]. When 

nanomaterials are introduced to the filling material, particle shedding has a minimal effect on tooth filling 

composition due to the small particle size. This leads to less apparent tooth roughness, such as when silica 

nanomaterials are used [33]. However, due to the small size of silica nanomaterials, there are a few potential health 

risks involved. Silica nanoparticles can cause reactive oxygen species (ROS) and additional oxidative stress. As a 

reference, there were higher amounts of ROS, lactate dehydrogenase (LDH), and malondialdehyde reported when 



Eisenstat et al. (2021): International Journal of Engineering Materials and Manufacture, 6(4), 225-241 

230 

treating non-small cell lung cancers or in other words bronchoalveolar carcinoma, with silica nanoparticles at an 

exposure rate of 10-100µg/mL [34, 35]. 

 Dental composites that release a disinfectant called chlorhexidine (CHX) have been found to have inferior 

mechanical properties than composites that do not release CHX [36]. However, as mentioned previously, preventing 

secondary caries are significant when applying dental fillings. Therefore, experiments have been conducted to 

investigate whether the antibacterial CHX can be present in the filling without jeopardizing the mechanical properties 

of the filling. CHX is used across the dental field due to its strong antibacterial activity alongside its low cytotoxicity 

in the oral cavity [36]. SBA-15 mesoporous silica nanoparticles (MSN) were mixed with CHX and then tested for the 

ejection of CHX, the flexural strength and modulus, surface roughness and the antibacterial activity against the same 

bacteria as mentioned previously, Streptococcus mutans and Lactobacillus [36]. 

To test the flexural strength and modulus, varying amounts of CHX (3%, 5% and 6.3%) were either mixed with 

the MSN or not mixed with the MSN and each mixture was then compared to a control set at times of 24- hours 

and 1 month [36]. Based on the results of the experiment, the flexural strength and modulus of the composites 

containing mixtures of CHX with MSN were greater for about every level of CHX percentage at both twenty-four 

hours and one month compared to the composites with only CHX. This can be visualized in Figure 2, as the blue 

and grey bars (CHX and MSN) reach higher magnitudes of Flexural Strength in MPa and Flexural Modulus in GPa, 

than the pink and green bars (pure CHX) [36].  

 

 

 

Figure 2: Flexural Strength and Modulus at varying levels of CHX percentages for pure CHX and CHX- MSN 

mixture at both 24 hours and 1 month [36] 

 

Regarding the release of CHX from the composite with respect to time, the composite with the purely CHX 

mixture released the CHX at a much more rapid rate at the start, however, very soon later the rate tapered off [36]. 

The goal for this composite is to have a continuous release of CHX to prevent secondary caries. Therefore, the 

composite composed of CHX and MSN mixture is preferable despite having a slower release rate of CHX at the 

beginning, as it has a more sustainable release of CHX over time, as seen in Figure 3 [36]. 

 



A Comparative Review of Material Properties for Current and Future Dental Filling Nanomaterials 

231 

  

 

Figure 3: Ejection levels of CHX with respect to time for pure and CHX-MSN mixture [36] 

 

In a different study conducted by Stewart et al. it was found that utilizing MSN allows for improved antimicrobial 

characteristics [37]. This is yet another study that proves the advantages of incorporating MSN into dental fillings, as 

they facilitate the release of antimicrobial agents more efficiently, ultimately aiding in the prevention of secondary 

caries [37]. They developed a dental adhesive, which combines the MSN and an antibacterial drug called octenidine 

dihydrochloride [37]. Their adhesive demonstrated no biocompatibility issues and performed well against biofilm 

formation through the controlled release of the octenidine dihydrochloride [37]. 

To test the surface roughness of the composite, each composite – pure CHX and CHX-MSN mixture, were 

submerged under water for a two-week period [36]. Upon removal from the water, it was evident that the composite 

with a mixture of CHX and MSN had displayed much greater wear resistance, which is of prime importance when 

working with dental fillings. Surface roughness is detrimental to a dental filling, as it yields greater wear on the filling 

[36]. The testing was conducted on composites of 5% CHX-MSN mixture and 5% pure CHX mixture, and the surface 

roughness’s prior to exposure of water were measured to be 0.344 and 0.311 respectively. However, after the 

exposure to water the surface roughness for each composite of 5% CHX-MSN mixture and 5% pure CHX mixture 

were measured to be 0.410 and 1.113 respectively [36]. On the surface of the composite with pure CHX, holes 

reaching further than 5 µm were visible, which can be seen in Figure 4 (B). The holes in the 5% CHX composite can 

be attributed to the greater surface roughness of 1.113 [36]. To calculate the percentage difference, the following 

equation is used:  

 

𝑃𝑒𝑟𝑐𝑒𝑛𝑡𝑎𝑔𝑒 𝐷𝑖𝑓𝑓𝑒𝑟𝑒𝑛𝑐𝑒 =
|𝑁𝑒𝑤𝑉𝑎𝑙𝑢𝑒−𝐼𝑛𝑖𝑡𝑖𝑎𝑙𝑉𝑎𝑙𝑢𝑒|

(𝑁𝑒𝑤𝑉𝑎𝑙𝑢𝑒+𝐼𝑛𝑖𝑡𝑖𝑎𝑙𝑉𝑎𝑙𝑢𝑒)

2

∙  100%      (4) 

 



Eisenstat et al. (2021): International Journal of Engineering Materials and Manufacture, 6(4), 225-241 

232 

 

 

Figure 4: Illustrations of the surfaces of (A) CHX-MSN composite, (B) CHX mixture composite, (C) Surface Roughness 

graphs for CHX-MSN composite, (D) Surface Roughness graphs for CHX composite [36] 

 

 

Through equation 4, better analysis of the change in surface roughness, and thus wear resistance can be made for 

the different composites of pure CHX versus that of CHX and MSN. It is evident from Table 2, that the wear resistance 

of the composite with the CHX and MSN mixture is far superior to that of just pure CHX, as the CHX composite 

underwent a 112.64 percent increase in surface roughness after being submerged in water for 14 days, compared to 

the 17.51 percent increase in surface roughness seen by the composite composed of CHX and MSN.  

 

Table 2: Percentage Differences for Surface Roughness of each composite mixture for before and after exposure to 

water [36] 

 

Mixture Surface Roughness Before Water 

(m) 

Surface Roughness After Water 

(m) 

Percentage Difference 

(%) 

CHX 0.311 1.113 112.64 

CHX-MSN 0.344 0.410 17.51 

 

 

Experimental trials demonstrate that Silica Nanoparticle infusion increases the physical properties of composite 

materials [36]. The addition of silica nanoparticles also demonstrated satisfactory antibacterial properties relative to 

control groups. In the tests conducted by J.F. Zhang et al. there was a significant number of bacteria present in control 

samples whereas the composite of CHX-MSN mixture had minimal or no bacteria present [36]. These observations 

can be attributed to the sustainable and more constant release of CHX from the composite with the CHX-MSN 

mixture. As a result of this sustainable release of antibacterial CHX, there is less time for the bacteria to accumulate 

on the surface of the filling. There is a need for consistent exposure to antibacterial substances [36]. J.F, Zhang et al. 

demonstrated that a consistent CHX release rate of 0.25 to 1.0 µg/mL for the composite consisting of the CHX-MSN 

mixture, will drastically lower the risk of bacteria growth and hibernation, and thus lowering the probability of 

secondary caries [36]. 

 



A Comparative Review of Material Properties for Current and Future Dental Filling Nanomaterials 

233 

Based on the findings of current available research, each type of nanoparticle presents various advantages, and 

all pose similar disadvantages associated with the health risks and toxicity of the nanoparticles. However, amongst 

the three most used nanomaterial dental fillings - carbon nanotubules, silver nanomaterials and silica nanomaterials 

- silica nanomaterials under controlled doses demonstrate the greatest material advantages. Silica nanomaterials 

improve wear resistance, improve physical and mechanical properties, reduce dental filling tooth roughness, improve 

the antibacterial properties, and are drastically less expensive relative to silver nanomaterials and carbon nanotubules 

alternatives [5,36]. Although there are health risks associated with silica nanomaterials, the same health risks are also 

present in carbon nanotubules and silver nanomaterials at greater frequency. Under controlled concentrations, silica 

nanomaterials produce minimal adverse effects [5]. 

 

Table 3: Advantages and Disadvantages of Currently Used Nanomaterial Dental Fillings [5,36] 

 

Nanomaterial Type Advantages Disadvantages 

Carbon Nanotubules 

-    Increased Surface Area for 

Reactivity 

-    Molds well with tooth 

-    Antimicrobial and Antibacterial 

Properties 

  

-    Potential Health Risks due to 

Small Particle Size. 

-    Potential Toxic effects 

Silver 

-    Antimicrobial and Antibacterial 

Properties 

-    Relatively Low Toxicity 

-    Potential Health Risks due to 

Small Particle Size 

-    Potential Toxic Effects 

Silica 

-    Inexpensive 

-    Improved Wear Resistance 

-    Antimicrobial and Antibacterial 

Properties 

-    Improved Physical and 

Mechanical properties 

-    Absorption Capacity 

-    Reduces Tooth Roughness 

-    Potential Health Risks due to 

Small Particle Size 

  

 

 

5 FUTURE DEVELOPMENTS OF NANOMATERIAL DENTAL FILLING APPLICATIONS  

5.1 Graphene Family Nanomaterials 

Graphene Family Nanomaterials (GFN) are potential alternatives to current nanomaterials used in dentistry. GFNs 

are comprised of many subclasses of graphene nanomaterials including graphene oxide (GO), reduced graphene 

oxide (rGO), graphene nanosheets (GNS), ultra-thin graphite and few layers graphene (FLG) respectively [39]. 

Differences between graphene types are attributed to variances in size, layer depth and surface properties as seen in 

Figure 5 [39].  

Much testing has been done regarding the biocompatibility of GFN. GFN tests have been performed in vivo and 

in vitro with results observing safe and potentially harmful thresholds of GFN concentration in the body. For 

graphene oxide, 50 µg/mL was determined to be the hypothetical toxicity threshold [37]. At concentrations over 50 

µg/mL, graphene oxide may carry damage to T-Cells and fibroblasts [39]. More research still needs to be concluded 

regarding GFN biocompatibility as no one determinant for toxicity – size, oxidation, iron content, etc. – has been 

established. 

The main area of interest regarding the medical and dental uses of GFN are their antibacterial properties. Relative 

to other materials currently being used in prosthodontic procedures, Graphene Family Nanomaterials – specifically 

graphene oxide – have shown to induce the complete elimination of microbial integrity. When tested against three 

bacteria commonly found in the oral cavity, Streptococcus mutans, Porphyromonas gingivalis, and Fusobacterium 

nucleatum, graphene oxide nanosheets at a concentration of 40 µg/mL were observed to be highly effective at 

inhibiting bacterial growth. Antibacterial properties of GFN are however dependent on concentration. By increasing 

graphene oxide concentration to 80 µg/mL, complete eradication of all Streptococcus mutans cultures was observed 

[39]. For reference, Streptococcus mutans is one the bacteria responsible for dental caries as previously mentioned, 

Porphyromonas gingivalis is a bacterium responsible for periodontitis, and Fusobacterium nucleatum is a bacterium 

responsible for root canal infection [39]. 

In terms of actual application as dental filling agents, GFN are being tested in combination with glass ionomers. 

Glass ionomers are structurally weak relative to other current filling materials. GFNs are looked at to reinforce glass 

ionomer structural properties and improve material strength [39]. Additionally, due to the antibacterial properties 

of GFN, research is being done in order to derive new dental adhesives to be used for filling processes. 

 



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234 

 

 

Figure 5: Allotropes of carbon nanostructures: (a) 0D Fullerenes; (b) 1D Carbon Nanotubes; (c) 2D Graphene; (d) 

3D Graphite. (e) Graphene Oxide is synthesized through graphite oxidation [39] 

 

 

5.2 Chitosan Nanomaterials 

Chitosan is an organic compound typically found in the exoskeletons of various shellfish [38]. As a nanomaterial, 

chitosan exhibits many beneficial properties that can be used in dentistry. One of many reasons why chitosan 

nanoparticle applications are being researched in dentistry is due to the experimental demonstrated effect of induced 

bone growth in the human body and oral cavity. When titanium implants are coated with chitosan nanoparticles in 

adjunct with bone growth protein BPM-2, ectopic bone growth was observed in mice [37]. Additionally, acceleration 

of bone regeneration was observed in mice when chitosan nanomaterials were infused with additional protein 

growth factors. Within regenerative dentistry, use of chitosan nanomaterials may offer alternatives to stopgap 

procedures like dental fillings. 

Chitosan nanoparticles also observe antibacterial properties. Antibacterial properties of chitosan nanomaterials 

are due to its chemical and polyatomic structure, as can be seen in Figure 6 [38]. 

 

 

Figure 6: Chemical Composition of Chitosan [38] 



A Comparative Review of Material Properties for Current and Future Dental Filling Nanomaterials 

235 

Researchers are pairing chitosan nanoparticles with various zinc-oxide-eugenol, calcium silicate and epoxy resin 

sealers, demonstrating improved antimicrobial properties of composite materials as a result. It is important for sealers 

to exhibit antimicrobial properties, as sealers are typically used for root canal procedures where there is direct 

exposure to nerve tissue. The exact mechanism for inducing antimicrobial properties in chitosan nanomaterials has 

yet to be determined. There is speculation as to whether antimicrobial properties of chitosan nanomaterials are a 

result of direct contact via material-bacterial interaction or via area effect [38]. 

A study conducted by Nair et al. on chitosan nanoparticles (CS-NPs) and zinc oxide nanoparticles (ZnO-NPs) 

against two strains of Enterococcus faecalis was used to show antibiofilm efficacy [40]. E. faecalis ATCC 29212 and 

OG1RF strains were each tested in five different environments and their average optimal densities were then 

compared after a 24-hour period [40]. After the 24-hour period, the two strains of E. faecalis - ATCC 29212 and 

OG1RF, created a biofilm and their biomasses were able to be analyzed using microtiter plate assay with the use of 

crystal violet [40]. The root canal sealer used in this experiment was Apexit Plus. Group 1 represents Apexit Plus with 

ZnO-NPs, group 2 is Apexit Plus with CS-NPs, group 3 was Apexit Plus by itself, group 4 was a positive control group 

with no sealers or nanoparticles, and group 5 was a negative, sterile control group. 

Group 1 was found to have the greatest reduction in average optical density in both strains of E. faecalis when 

compared to the positive control group. However, also group 2, the environment with Apexit Plus with CS-NPs, 

demonstrated improved antibacterial activity compared to that of group 4, the positive control environment [40]. 

A second study of confocal laser scanning microscopy (CLSM) was also conducted with 1 week old biofilm to 

observe the antibacterial effectiveness [40]. The two strains of E. faecalis in their same four individual groups, as in 

the first experiment, were analyzed by their thicknesses. 

Through investigation of ATCC 29212 the data showed a significant reduction in thickness of group 1 compared 

to the other groups. Also, once again group 2, the environment with Apexit Plus with CS-NPs, demonstrated 

improved antibacterial activity compared to that of group 4, the positive control environment for the ATCC 29212 

strain [40]. However, all groups of OG1RF strain had little to no change in their biofilm thickness after 1 week [40]. 

A third study of the biofilms was conducted using 200 µL of solution from group 1, group 2 and group 3 [40]. 

They were placed in glass wells and were left for 24 hours at 37 ℃. After the 24-hour period, they were removed 
from the wells dyed with a propidium iodide stain (which is used to differentiate between living and dead bacterial 

cells by the colours green and red respectively) and a biofilm was placed on top [40]. These were left to rest for 10 

minutes in the dark. 

It was seen that group 3 with E. faecalis ATCC29212 had extreme amounts of living bacterial cells compared to 

dead bacterial cells. Whereas groups 1 and 2 effectively diminished the presence of the two strains at a much higher 

rate. This is because the thickness notably decreased. group 1, with E. faecalis OG1RF, killed many of the bacterial 

cells. However, the thicknesses in group 1 with E. faecalis OG1RF and group 2 with E. faecalis OG1RF had not been 

compromised, meaning that the thickness of E. faecalis OG1RF were not influenced by ZnO-NPs or CS-NPs [40].  

As mentioned previously, the biocompatibility of products looking to be employed in the dental profession are 

of prime importance in order to protect patients from potential cytotoxic effects. In a study conducted by Elgendy 

et al. chitosan nanoparticles were compared to propolis, a resinous substance that comes from beehives, as well as 

non-nanosized chitosan nanoparticles [41]. Propolis, in recent years, has gained interest in its applicability in 

restorative dentistry due to its improved antibacterial activity [42]. Elgendy et al. proved however through their 

study, in which dental pulp stem cells were exposed to chitosan nanoparticles, propolis nanoparticles and standard 

chitosan particles, that the chitosan nanoparticles exhibited the least cytotoxic effects and resulted in the least 

characteristic cell changes [41].  

Despite promising bone regenerative and antibacterial properties chitosan nanomaterials are not without their 

drawbacks. Chitosan nanomaterials exhibit weak processing and mechanical properties, as well as complete 

insolubility in many common organic solvents [38]. Researchers are attempting to mitigate these drawbacks by 

infusing chitosan nanomaterials with various other organic and inorganic nanomaterials. 

 

5.3 Zirconia Nanomaterials 

Zirconium Dioxide (Zr𝑂2) - Zirconia - observes a crystalline structure, a melting point of 2,715 ℃, and resembles the 
colour of healthy teeth [43]. Due to these characteristics, Zirconia is a sought-after ceramic in the dental industry [44]. 

Its crystalline structure increases its strength, durability, weatherability, and erosion resistance. At high temperatures, 

stable Zirconia permits the free movement of oxygen ions throughout its crystalline structure, increasing electrical 

conductivity making it a very useful electro-ceramic material [45]. As a chemical oxide, zirconia is insoluble in water 

decreasing bacterial adhesion [46,47]. Using advanced dental technology, three-unit zirconia ceramics show 

promising results regarding Fixed Partial Dentures (FPD) by computer aided design/computer aided manufacturing 

(CAD/CAM) [48]. In vitro experiments determined that Zirconia fulfills many of the characteristics considered 

necessary for dental fillings and dentures [48]. Biomedical implementations of zirconium have been increasing over 

the years and continue to be used throughout the field [49]. 



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236 

 

 

Figure 7: Anatomical crystalline arrangement of Zirconia (ZrO2) [50] 

 

 

5.4 Gold Nanoparticles 

Gold nanoparticles are gaining relevance in the field of dental fillings, due to their potential use as inert carriers for 

medical purposes and since they are harmless, precise, and rigid [51, 52]. Elemental gold or its ions, can be absorbed 

in the gastrointestinal tract. Data regarding the oral toxicity of elemental gold is limited [51]. There were tests done 

on rats using a single dose of 2000 mg nanoparticles/kg of body weight. The lack of information regarding multiple 

doses has raised concerns [51]. Skin rashes have been documented in humans following the ingestion of liquors 

containing gold. In vitro studies show that gold nanoparticles in mammals induce DNA damage [51]. There should 

be more time and consideration taken to understand the effects of gold nanoparticles, for how frequent they are 

used in dental fillings. 

 

6 PREVENTATIVE MEASURES AGAINST PRIMARY OR SECONDARY CARIES PRIOR TO DENTAL FILLINGS  

As mentioned before, the most common problem seen by dental professionals are those of dental caries, which cause 

dental cavities. However, another major cause for dental appointments are the failures of the presently used dental 

fillings, whether it be due to mechanical failure or as a result of secondary caries, as previously mentioned. 

Advancements in the Biomedical Engineering research of nanomaterial based dental fillings is a reactionary solution 

to the problem. However, there are also potential proactive solutions to dental caries. In other words, there are 

Biomedical applications of nanomaterials, which can prevent the problem of dental caries in the first place. For 

example, there are developments for a toothbrush with nanomaterials. In between the bristles of the toothbrush, 

colloidal gold or silver will be placed which can lead to an improvement in dental health and thus a reduction in 

dental caries [53]. Colloidal silver or gold is simply their respective nanoparticles submerged in a solvent [54]. 

Negative phosphate molecules gravitate towards the positively charged silver and gold, which then aids in the 

destruction of biofilms and/or plaque [53]. 

 

6.1 Starch Nanoparticles and Early Diagnosis of Caries 

Nanomaterials are now being recognized as a method to limit the need for dental professionals from needing to 

carry out full dental filling procedures. Dental professionals run the risk of overlooking early signs of caries through 

the use of visual and tactile exam tools [55]. Currently, X-Ray imaging is a popular method for caries detection, 

however this requires the caries to be significantly developed, otherwise the X-Rays will not detect them [55]. 

Regardless, when operating with these procedures, the solution is to resort to the “drill and fill” method, which is 

not ideal due to its invasive nature [55]. At the onset of caries development, very small holes begin to develop in 

the enamel (outer layer) of the tooth. As a result, Greenmark, a healthcare start-up, received approval from the Food 

and Drug Administration agency in March, 2021 for a product called 𝐿𝑢𝑚𝑖𝑐𝑎𝑟𝑒𝑇𝑀Caries Detection Rinse, which 
utilizes the benefits of starch nanoparticles [55]. Molecules within the starch nanoparticles glow in the presence of a 

luminated blue curing light, as seen in Figure 8.  



A Comparative Review of Material Properties for Current and Future Dental Filling Nanomaterials 

237 

 

 

Figure 8: Reproduced Figure with Permission from Greenmark Biomedical Inc Illustrating the Starch Nanoparticles’ 

Ability to Fluoresce [55] 

 

As summarized in Figure 9, a patient will start by rinsing their mouth out with the Greenmark Rinse, and as they are 

rinsing, the miniscule starch nanoparticles are able to enter through the tiny porosities in the enamel and then get 

trapped around the early caries [55]. The patient then rinses their mouth, essentially ridding the oral cavity of all 

substances other than the starch nanoparticles in the porosities [55]. When the dental professional then shines the 

blue curing light, the starch nanoparticles then fluoresce, revealing the locations of the early caries, which can then 

be treated non-invasively [55]. 

Furthermore, Greenmark is also developing a product called 𝐶𝑟𝑦𝑠𝑡𝐿𝐶𝑎𝑟𝑒𝑇𝑀  Restorative Gel, which contains starch 
nanoparticles bonded with calcium and phosphate, two of the most important minerals that are reduced in 

concentration during the onset of caries [55]. As mentioned previously, the starch nanoparticles can penetrate 

through the openings in the enamel and then attach to the developing caries [55]. Once all of this takes place, the 

starch particles disintegrate, thus allowing the now detached calcium and phosphate to re-mineralize the decayed 

tooth [55]. Part of why the use of starch particles is so beneficial is that there is no safety concern due to their 

biocompatibility and degradability in the oral cavity [55]. 

 

 

 

 

Figure 9: Privately Redistributed Figure from Greenmark Biomedical Inc Explaining the Step-by-Step Procedure of 

How the 𝐿𝑢𝑚𝑖𝑐𝑎𝑟𝑒𝑇𝑀Caries Detection Rinse Works 
  



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238 

6.2. Glycine Guided Nanoparticles 

Minimal Invasive Dentistry (MID) is a dental practice where dentists work to preserve original dental tissue. This can 

include performing early but small cavity fillings, in order to prevent significant future damage to the tooth. Dental 

decay is a result of the hydroxyapatite (HAP) mineral ions loss on the enamel. This is known as demineralization 

[56]. Under MID, the primary method used to treat tooth decay is fluoride application. Fluoride treatments provide 

remineralization to the demineralized tooth. There are however drawbacks to fluoride treatment, as mineral ions in 

fluoride are difficult to maneuver [56]. Remineralization treatments should have the same micro-architecture and 

organization as the original biological mineral crystals. Research demonstrated that HAP@ACP core-shell 

nanoparticles can be organized just like the original biological mineral crystals. Experiments determined that after 48 

hours of HAP@ACP, nanoparticles with Gly formed mineral-like enamel crystals [56]. 

 

6.3. Nanomaterial Toothpastes 

A Japanese study was conducted to investigate the possibility of nanomaterial infused toothpaste. In this study, nano-

hydroxyapatite particles (NHAP) were incorporated into a toothpaste solution [57]. It was observed that the 

nanoparticles that were infused in the toothpaste significantly increased tooth enamel microhardness relative to 

toothpaste not infused with nanoparticle solution. Experimental trials demonstrated a 56% reduction in cavity 

formation of nanomaterial infused vs. non-nanomaterial infused toothpastes. [57]. 

Additional experiments were conducted to test the influences on tooth hardness and the remineralization effect 

using 3% nanosized sodium tri-metaphosphate infused toothpaste [58]. The remineralization effect pertains to the 

prevention of a caries progressing into a cavity, which is a later stage [59]. It was found that the addition of nanosized 

sodium tri-metaphosphate had significant influences on both tooth hardness and remineralization. Enamel hardness 

increased by 20% while the remineralization effect of the enamel increased by 66% [58]. There has also been 

additional research into the use of nanoparticles in mouthwashes, which found that the addition of nano-calcium 

fluoride reduces the potential for caries [57]. 

 

6.4. Silver and Calcium Phosphate Nanoparticle Dental Adhesives 

A study was conducted to test the effectiveness of adding silver nanoparticles (NAg) and amorphous calcium 

phosphate nanoparticles (NACP) to an adhesive in breaking down biofilms, remineralization of both the dentin and 

enamel of the tooth, and the bond strength of the dentin [60]. Low percentages of NAg were added to the adhesive, 

while larger percentages of the mass of the adhesive was occupied by the NACP [58]. It was found through this 

experiment that the additional nanoparticles had a significant positive effect on the antibacterial properties of the 

adhesive and the remineralization of the dentin and enamel. Furthermore, while the dentin bond strength was of 

prime concern, it was found to not be affected by the additional nanoparticles [60]. 

 

7 CONCLUSIONS 

There has been a great deal of research done regarding dental filling nanomaterials and nanoparticles. Not one 

material has proven to have all the beneficial qualities/characteristics desired for the filling. However, there are 

materials that have stood out as being a better option. As more research is being piloted, more knowledge is available 

to professionals in the industry, allowing them to give patients the best dental care possible. 
 

1. Promising current research regarding dental filling nanomaterial applications involve nanocomposites, dental 

cement, glycine guided nanoparticles, nanomaterial resins, silica coated nanomaterials, silver coated and other 

metallic based nanoparticles. 

2. Of the three most used nanomaterial dental fillers - carbon nanotubules, silver nanomaterials and silica 

nanomaterials - silica nanomaterials were observed to be the best current option due to its low cost, improved 

wear resistance, improved physical and mechanical properties, improved antibacterial properties and 

comparable toxicity levels under controlled concentrations. 

3. The most important properties that were investigated with dental fillings nanomaterials are the resistance to 

wear, toxicity and the overall biocompatibility of the material. For the biocompatibility of dental filling 

nanomaterials, several reactive properties were analyzed, those being corrosion by pH, temperature, protein, 

saliva, oral health conditions, and diet. 

4. The current literature on the cytotoxic effects of various nanomaterials is conflicting, and thus more research 

should be conducted into the safety of introducing nanomaterials into the oral cavity. 

5. Developmental strides are being made regarding future applications of graphene family nanomaterials (GFN), 

chitosan nanomaterials and gold nanoparticles for use in dental filling and dental filling processes.  

6. Starch nanoparticles are currently being utilized to create new products that aid in detection of early caries, 

as well as treat early caries by recrystallizing of the decayed tooth.  

7. Innovations regarding cavity prevention via nanoparticle use in toothpastes are being seen. With continued 

research, nanomaterials offer solutions to dental filling problems not previously available through traditional 

dental filling materials. 

  



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239 

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