EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by ....
Transcript of EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by ....
![Page 1: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/1.jpg)
i
EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS FILLER LOADS ON MECHANICAL AND PHYSICAL PROPERTIES OF FLOWABLE
COMPOSITE RESINS
by
SHASHIKANT SINGHAL
JOHN O. BURGESS (CHAIR) AMJAD JAVED
DENIZ CAKIR-USTUN JACK E. LEMONS VINOY THOMAS
A THESIS
Submitted to the graduate faculty of The University of Alabama at Birmingham, in partial fulfillment of the requirements for the degree of Master of Science
BIRMINGHAM, ALABAMA
2011
![Page 2: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/2.jpg)
ii
Copyright by
SHASHIKANT SINGHAL 2011
![Page 3: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/3.jpg)
iii
EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS FILLER LOADS ON MECHANICAL AND PHYSICAL PROPERTIES OF FLOWABLE
COMPOSITE RESINS
SHASHIKANT SINGHAL
BIOMATERIALS
ABSTRACT
Dental composites are important in the spectra of restorative materials. Ability to
match the color of natural dentition is an appealing characteristic of composite
restorations. Additionally, they can be bonded physically to the tooth, which limits the
amount of tooth preparation required and thereby conserves healthy tooth structure. In
relation to other restorations like amalgams, non–metallic compositions of dental
composites have exhibited good biocompatibility. The dental composites are composed
of a resin matrix containing a blend of bis-GMA (bis-phenol A-glycidyldimethacrylate)
or urethane dimethacrylate (UDMA) along with TEGDMA
(tetraethylglycidylmethacrylate). Novel techniques for the reinforcement of these resin-
based composites continue in a research and development phase, since the existing resin-
filler systems may not be suitable for long term applications in large restorations. The
nanofillers reinforced composite resins had shown promising results. Silica-based
nanoparticles and clusters are blended with larger-sized fillers and are available
commercially for restoring large posterior restorations. These nanoparticles, offer poor
crack blunting ability due to their shape and very small diameters and also improves the
stiffness of the composites. However, addition of fibers, by virtue of their geometry and
very large aspect ratios, may provide better resistance to fracture. The objective of this
![Page 4: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/4.jpg)
iv
study was to study the effect of silica nanofiber (SNF) and a mixture of Silica filler
particles (SFP) reinforcement on the fracture toughness, flexural strength, three body
wear, polymerization shrinkage, rheology, gloss and degree of conversion of bis-
GMA/TEGMA based composite resin.
Silica nanofibers (SNF) were fabricated using electrospinning and incorporated
20wt %, 35.8wt% and mixture of 20 wt% of SNF and SFP in ratio of 1:1 (20wt% H), into
a bis-GMA/TEGDMA matrix. Experimental groups composed of clear resin and
traditionally filled flowable resin (PermaFlo, Ultradent) were tested as negative and
positive controls respectively. Data were analyzed using one way ANOVA and Tukey’s
test. Experimental group with 20 wt% of SNF and SNP mixture showed highest fracture
toughness, flexural strength, wear resistant, degree of conversion. 20wt% showed highest
gloss and 35.8wt% showed best rheological properties. Significant increase in all tested
properties (p<0.001) was seen after addition of nanofiber.
![Page 5: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/5.jpg)
v
DEDICATED:
To my parents, brother, sister-in-law, fiancée and my mentor Dr. John O. Burgess
![Page 6: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/6.jpg)
vi
ACKNOWLEDGEMENTS
I would like to take this opportunity to convey my sincere gratitude to my mentor,
Dr. John O. Burgess, who has been a constant source of guidance and encouragement
throughout the course of my biomaterials program and providing me so many
opportunities to be part of both in-vitro and clinical studies. Under his undaunting
support, I not only learned the basics of graduate research, however he nurtured me to
take best out of me.
I express my sincere thanks to Dr. Deniz Cakir-Ustun and Mr. Preston Beck for
sharing their expertise and helping me with all experimental procedures during this
research work and all other research projects which I got the opportunity to do during my
graduate program. Under their guidance, I got excellent opportunity to develop an
understanding of the merits of meaning full research.
I am thankful to the academic and administrative staff of the UAB Centre of
Nanoscale Materials and Bio-integration for supporting my research work specially Dr.
Vinoy Thomas. I would like to personally acknowledge his timeless efforts, countless
ideas and sincere conversations which always guided me to move further during my
research work. Under his guidance, I got the opportunity to develop more ideas of using
nanotechnology in the field of dentistry.
I would also like to sincerely appreciate the support of faculty specially Dr.
Derrick Dean and Dr. Robin Foley and all graduate students (Ayesha Swarn, Dr. Reginna
![Page 7: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/7.jpg)
vii
Scarber and John Tipton) of Department of Material Science and Engineering for
supporting and guiding me throughout my research project.
A special mention to my seniors (Dr. Ian Mugasia, Courtney Michelson and Dr.
Gowri Natarajarathinam) and colleagues (Dr. Shreya Shah and Dr. Bala
Baladhandayutham) whose timely inputs and friendship I shall always cherish. I thank
Dr. Sridhar Janyavula and Dr. Dave Kojic for all their support and encouragement
always and being my pillars of support in Birmingham. I will always carry with me, fond
memories of this institute in which I found a second home.
I am extremely thankful to my parents and brother, sister-in-law, fiancée and my
friends in India for their wishes, support, encouragement and trust which always inspire
me to perform my best.
![Page 8: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/8.jpg)
viii
TABLE OF CONTENTS
Page
ABSTRACT ......................................................................................................................iii
DEDICATION ....................................................................................................................v
ACKNOWLEDGEMENTS ...............................................................................................vi
LIST OF TABLES .............................................................................................................xi
LIST OF FIGURES ..........................................................................................................xii
1 INTRODUCTION ...........................................................................................................1
2 OBJECTIVES ................................................................................................................15
3 NULL HYPOTHESIS ………………………………………………………………...16
4 LITERATURE REVIEW ..............................................................................................17
4.1 Dental Caries and Restorative materials ...............................................................17
4.2 Dental Composites ................................................................................................18
4.2.1 Based on Dimension. ...................................................................................22
4.2.2 Based on Material. .......................................................................................23
4.2.3 Based on Geometry. .....................................................................................24
4.4 Fabrication of Nanofibers......................................................................................24
4.4.1 Drawing.........................................................................................................25
4.4.2 Molecular Self–Assembly ............................................................................26
4.4.3 Template Synthesis ......................................................................................26
4.4.4 Phase Separation ..........................................................................................27
![Page 9: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/9.jpg)
ix
4.4.5 Electrospinning ............................................................................................27
5 MATERIALS ................................................................................................................32
5.1 Electrospinning solution .......................................................................................32
5.1.1 Sol Precursors ..............................................................................................32
5.1.2 Binder Polymer ............................................................................................33
5.2 Experimental Groups.............................................................................................34
6 METHODS ....................................................................................................................35
6.1 Fabrication of SNF ................................................................................................35
6.1.1 Preparation of Silica Sol ..............................................................................35
6.1.2 Electrospinning ............................................................................................36
6.1.3 Calcination ...................................................................................................37
6.2 Characterization of Nanofibers……………..……………………………………38
6.2.1 Scanning Electron Microscope (SEM) ........................................................38
6.2.2 Fourier Transform Infrared Spectroscopy (FTIR) .......................................38
6.2.3 X-Ray diffracrtion………………………………………………………….38
6.3 Silanization of Fibers and Sample Preparation .....................................................39
6.3.1 SNF Incorporation into Dental Resin ..........................................................40
6.4 Characterization of Experimental Groups ............................................................40
6.4.1 Rheology ......................................................................................................40
6.4.2 Gloss……………………………………………………………………….41
6.4.3 Degree of Conversion (DC) .........................................................................42
6.4.4 Polymerization Shrinkage ............................................................................43
6.4.5 Wear Testing ................................................................................................44
![Page 10: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/10.jpg)
x
6.4.6 Fracture Toughness and Flexural Strength……...........................................47
7 RESULTS AND DISCUSSION ....................................................................................51
7.1 Characterization of Nanofibers .............................................................................51
7.1.1 Scanning Electron Microscope (SEM) ........................................................51
7.1.2 Fourier Transform Infrared Spectroscopy (FTIR) and Energy dispersive
spectroscopy (EDS) .....................................................................................55
7.1.3 X-Ray Diffraction (XRD)………………………………………………….56
7.2 Characterization of SNF reinforced composite resin ............................................57
7.2.1 Rheology ......................................................................................................57
7.2.2 Gloss……………………………………………………………………….58
7.2.2 Degree of Conversion (DC) .........................................................................59
7.2.3 Polymerization Shrinkage ............................................................................61
7.2.4 Wear Testing ................................................................................................62
7.2.5 Fracture Toughness and Flexural Strength ..................................................65
8 NULL HYPOTHESIS REJECTION…………………………………………………71
9 CONCLUSIONS ...........................................................................................................72
LIST OF REFERENCES ..................................................................................................74
![Page 11: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/11.jpg)
xi
LIST OF TABLES
Table Page
1 Filler loading and filler size distribution in different composite systems [38]...............14
2 Represents 3 experimental groups with different filler loads (wt%) and Clear Resin and PermaFlo (Negetive and positive control respectively)…...................31
![Page 12: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/12.jpg)
xii
LIST OF FIGURES
Figure Page
1 The market share of type of dental restorations placed in the United states in the year 2005 [3] ..........................................................................3
2 Classification of tooth colored restorative materials ...................................................3
3 The effect of high polymerization shrinkage (a) and low ploymerization shrinkage (b) on the bond between restoration and the tooth .....................................7
4 Chemical structures of (a) bis-GMA and (b) TEGDMA ........................................19-20
5 Represents the silicon bridging between the polymer matrix and inorganic fillers ............................................................................................................................21
6 Chemical structure of γ-mercaptopropyl-trimethoxysilane.........................................21
7 Schematic depicting the augmentation in packing fraction with different sizes of fillers ................................................................................................23
8 Schematic of continuously drawn array of fibers on a silicon substrate adapted from the work done by Nain et al [77]……………........................................25
9 Template Synthesis of Nanowire / Nanotube Heterostructures [82] ...........................22
10 Schematic of the electrospinning apparatus [84]..........................................................28
11 Chemical structure of tetra (ethyl orthosilicate) (TEOS) .............................................33
12 Molecular structure of Polyvinylpyrrolidone (PVP).....................................................34
13 Depiction of technique for preparing the silica sol. HCl is added drop-by-drop to the ethanol, TEOS and distilled water blend, followed by a heat treatment.............36
14 Schematic of the electrospinning apparatus consisting of a syringe with polymer solution, high voltage source attached to the needle tip and a grounded static aluminium collector ............................................................................................37
![Page 13: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/13.jpg)
xiii
15 Diagrammatic representation of X-Ray diffraction Technique [103]………………...39
16 Specifications of a parallel plate rheometer in oscillatory mode…............................. 38
17 The ACUVOL showing the rotating pedestal for sample placement
and camera for real time imaging….…………………………………………………44
18 (a, c) Composite specimen build up incrementally using hand instruments, (b) light curing the final layer of the composite specimen under a glass slide, (d) mounted specimen (center) on brass holder, (e) polishing of the mounted specimens and (f) the Alabama wear simulator …......................................46
19 Proscan volumetric shrinkage machine with samples placed for scanning .................47
20 Specimens dimensions and applied loads in a fracture toughness test.........................48
21 Systematic representation of three point bend test……...............................................49
22 Represents silica nanofibers (a, b) produced at 20 wt% precursor solution. Uniform diameter fibers were observed. No bead or droplet formation was observed………………………………………………………………………….52
23 (a,b) represents SNF after calcinations at 4000x and 14,000x……………………….53
24 Represents silica nanofibers diameter distribution before (PVP-SNF) and after calcinations (SNF-C)……………..…………………………………………….54
25 Represents FT-IR spectrum comparing calcinated and un-calcinated silica nanofiber………………………………………………………………………..55
26 XRD of SNF with peak at 2ϴ angle of 21º shows amorphous silica………………...56
27 Represents change in viscosity of different experimental groups (20wt%, 35.8wt% and 20wt% H) compared with unfilled and highly filled (PermaFlo) composite resins…………………………………………………...58
28 Represents comparison of mean and SD gloss values of all tested groups…………..59
29 Represents comparison of degree of conversion among tested groups (Mean±SD)…59
30 Degree of conversion was measured by comparing absorption peaks of aliphatic C=C (1638 cm-1) and aromatic C-C peaks (1608 cm-1) using equation 5…..60
![Page 14: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/14.jpg)
xiv
31 Represents comparison of polymerization shrinkage percentages and standard deviation values of all experimental groups (Mean±SD)…………………...62
32 (a,b,e,f) represents superimposed scans generated using PROFORM software in which, top surface represents pre-wear surface and bottom image represents post-wear image of all groups 20wt%, 35.8wt%, 20wt% H and Permaflo respectively. (c,d,g,f) represents wear pattern observed in all groups in same order as mentioned above……………...63
33 Comparison of volumetric loss (mm3) among all experimental groups (Mean±SD)…………………………………………………………………………...64
34 Comparison of KIc values (with Standard deviations) for all 5 tested groups (Mean ± SD)…………………………………………………………………..65
35 SEM images of fractured surfaces: (a, b) clear resin specimens with distinct ridges formed due to a brittle fracture, (c) PermaFlo specimen with areas of irregular cleavages……………………………………………………...67
36 Shows distribution of various filler loads and fracture pattern in 20 wt% (a), 35.8 wt% (b) and 20 wt% H (c). Arrows in a) indicates fiber pull out and SNF projected from resin matrix and crack propagation. Arrows in b) represents fracture pattern and projected SNF from resin matrix. Arrows in c) represent fiber pull-out, non uniform distribution of SFP……………...68
![Page 15: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/15.jpg)
1
1 INTRODUCTION
Dental caries is one of the world’s most common diseases which is affecting
approximately 80% of the developed countries population [1]. As per the report by U.S.
department of health and human services, in United States, dental caries is a most
common chronic childhood disease, diagnosed at least five times more frequently than
asthma [2]. Management of carious teeth is necessary and it follows a multilevel
approach, comprising early interventions, such as topical fluoride application, to more
aggressive treatments including the replacement of lost tooth structure by restorative
measures. Dental wear, abrasion, erosion of tooth structure, trauma are some other
reasons for the placement of dental restorations. Based on dental insurance claim data, in
the year 2005, an estimated total of 166 million restorations were performed in the United
States alone [3]. This increased demand for dental restorations has encouraged
researchers to search for innovative and superior dental restorative materials.
The spectrum of dental restorative materials has widened considerably since the
treatment was first practiced several millennia ago. During Egyptian civilization, gold
wire, ox bone and wood were often used as tooth replacement materials. Marco Polo et al
mentioned the use of gold leaves as decoration on teeth in Chinese civilizations around
1280 AD [4]. During 14th century, a textbook named, Chirurgia Magna, was written by
the famous French surgeon Guy de Chauliac, presented dental disease in a new
perspective.
![Page 16: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/16.jpg)
2
In 15th century, Giovanni de Arcoli (Italy) introduced metallic restorations, such
as gold foils, and was made popular as dental materials in 1728 by a French physician,
Pierre Fauchard, when he started using gold as restorative material for filling teeth and
making denture bases. Today, dental restorative materials are broadly classified into
various categories- metal alloys, polymeric resins and ceramics.
Metallic alloys, such as dental amalgams, have been in use since the early
nineteenth century. Amalgam technically means an alloy of mercury mixed with any
other metal, however dental amalgam is an alloy of mercury with silver-tin amalgam
alloy. The longevity of dental amalgam in posterior restorations had been well
established with a survival rate of 80% according to a 12.5 year clinical study [5]. The
most accepted explanation for the longevity of dental amalgam restoration is the leaching
of corrosion products from these restorations which further seals the tooth-restoration
interface. This seal prevents further the microleakage of bacteria and bacterial products
into the tooth structure and eliminates subsequent damage from dental caries.
Additionally, dental amalgam restorations have also exhibits a similar wear rate as of the
natural dentition. However, with increasing demand of tooth colored restorations and
reports of mercury toxicity has led to the steady decline in their popularity.
With the increasing demand tooth colored restorations led to the emergence of
composite resins in 1962, after R.L Bowen developed the bis-GMA (bisphenol–A-
glycidyl methacrylate) resin matrix. Along with resin matrix, these composites also
consisted of inorganic fillers, such as radio-opaque glass, quartz, or ceramic particles.
Initially, their use was confined to aesthetics governed area like anterior teeth, however,
with the increase in preference for tooth-colored restorations, among dentists and
patients, use of resin composites has increased [6, 7] as seen in Figure 1.
![Page 17: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/17.jpg)
3
Fig. 1. The market share of type of dental restorations placed in the United states in the year 2005 [3]. Compomers, glass inomer cements, composite resins and ceramics are widely
used tooth-colored restorative materials today. As observed in Figure 2, each class of
tooth colored restoration is further sub-categorized based on the modifications included
in the composition of the base material.
Fig. 2. Classification of tooth colored restorative materials.
![Page 18: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/18.jpg)
4
Among tooth colored restorative materials, composite resins, glass ionomer
cements and compomers are used as direct restorations and have shown acceptable
durability in smaller tooth preparations [8]. However, studies have shown that with
improved control over filler composition and loading and filler-matrix chemistry, has led
to significant improvements in the properties of these composite resins [9].
Studies have shown that these dental composite resins can be successfully used in
Class I (one missing tooth wall) and Class II (two missing tooth walls) restorations [10].
Collins et al found that the average annual failure rate of a posterior composite restoration
is about 1.2 % during 8 year follow up [11], with wear rates ranging between 7 - 12
µm/yr [9]. Studies also show that dental cements reinforced with resins have also shown
acceptable durability in restoring Class I and II cavities in primary teeth [12].
The primary constituents of the resin matrix are resin monomers and an
initiator/catalyst system for polymerization. In spite of improvements in resin composites,
material limitations exist which restrict the use of resin composite as a posterior
restorative material. Clinically, resin restorations are difficult and require more placement
time than a similar sized amalgam restoration [13]. Interproximal contacts are difficult to
obtain since composite is a paste material that shrinks during polymerization.
The initiator/catalyst system for direct RBC may be chemically or light activated.
With chemically activated polymerization, benzoyl peroxide is the initiator and a tertiary
amine, e.g., dihydroxyethylparatoludine (DHEPT) or sulfinic acid initiator is the activator
[14]. Once the two paste chemically-cured RBC is mixed, the initiator and activator
contact and polymerization begins. After a few minutes the polymerization produces a
gel (solid) where the polymer is cross linked enough to form a cohesive mass which may
![Page 19: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/19.jpg)
5
be finished and polished. In the 1980's visible light-cured (VLC) resin-based composites
were introduced to the dental profession. These resins systems became very popular and
now are the dominant, directly placed esthetic material.
Visible light-cured RBCs are single paste materials polymerized with visible light
energy. VLC RBC allow the operator to control setting time; require no mixing, have
fewer voids, greater strength, greater fracture toughness; better shade selection, improved
color stability and higher polymerization conversion rates than chemically activated
RBC. VLC RBC polymerizes by free radical polymerization. Visible light-cured RBC
has a photo-initiator and accelerator/catalyst system for polymerization. The
photoinitiator absorbs light energy (photons) emitted from the curing light and directly or
indirectly initiates polymerization. Photoinitiators are diketones, such as
camphoroquinone, activated by visible light, in the presence of an amine
accelerator/catalyst, e.g., dimethylamino ethylmethacrylate (DMAEM). The activated
diketone/amine complex initiates the polymerization of the dimethacrylate resin
monomers. VLC RBC contains a lower concentration of amine accelerators than
chemically cured RBC; which increases the color stability of VLC RBC compared to
chemically activated RBC [15-17]. Camphoroquinone is a commonly used photoinitiator
with major absorption of visible light wavelengths in the 460-480 nm (blue) range.
RBCs may contain a combination of photoinitiators, each requiring its own specific
wavelength for maximum reactivity. Camphorquinone has a maximum absorption
spectrum of 468 nm, which is close to the peak spectral output of the LED curing lights
[18]. Since different composite resins have different photoinitiators, the wavelength of
light absorbed by the photoinitiator for maximum polymerization should be provided for
![Page 20: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/20.jpg)
6
each composite [19]. Percent conversion or the ratio of double bonds converted to single
bonds indicates the extent of polymerization. Composites with higher percent conversion
have greater mechanical properties, wear resistance, better color stability and are more
biocompatible which contributes to maximum restoration longevity [20].
During polymerization of resin-based composite the distance between the
monomers decreases as the carbon atoms bond together and molecular movement
decreases. With present day RBCs this shrinkage ranges from 1.5% to 3.0% per volume.
Composite resin placed in a cavity preparation is confined by the preparation. Shrinkage
of the composite resin transfers stress to the cavity walls. Polymerization shrinkage can
tear the adhesive bond from the tooth [21], or pull the opposing cusps together by
deforming the tooth depending upon the thickness of the remaining tooth [22]. Shrinkage
of the RBC can fracture the marginal tooth structure, tear the adhesive or cause tooth
structure to deform which increases microleakage, postoperative sensitivity, staining and
recurrent caries (Figure 3). Increasing the filler content of RBC minimizes resin content
and reduces the shrinkage, and increases the stiffness or (modulus of elasticity). The
magnitude of the contraction stress is related to the cavity configuration [23], the
compliance of the composite and the surrounding tooth structure [24] the composite resin
degree of conversion and the conversion rate of the composite which is related to the
modulus of the composite [25]. As RBC polymerizes, the amount of stress generated to
the surrounding tooth depends in part upon the rate of modulus development. High
modulus composites with rapid conversion rates transfer stress to the surrounding tooth
structure more rapidly than lower modulus materials with slow conversion rates.
![Page 21: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/21.jpg)
7
Fig. 3. The effect of high polymerization shrinkage (a) and low polymerization shrinkage (b) on the bond between restoration and the tooth
Another significant limitation of these materials is a chipping fracture that occurs
commonly in larger restorations. Improved mechanical properties may be obtained by
varying filler size and shape, volume fraction loading, composition of the resin matrix
and filler-matrix interfacial bonding [26]. Silanization of silica filler particles improves
filler-matrix bonding and increases mechanical properties of commercially produced
composites [27].
Since the introduction of dental resin-based composites as posterior restorative
materials, their clinical behavior has been determined by their mechanical properties [28].
During the ‘70s and ‘80s the main failure mechanisms of composite restorations were
(a)
(b)
![Page 22: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/22.jpg)
8
insufficient wear resistance, loss of anatomic form, and degradation of the restoration
[29]. The improvement in filler technology resulted in more wear resistant composites
and changed the failures improving composite restoration performance [30]. Wear can
cause tipping of the occlusal plane (a plane passing through the occlusal or biting
surfaces of the teeth), leading to imbalances in the transmission of forces to the tempero-
mandibular (jaw) joints. Over the years, this may lead to chronic inflammation of the
joint space, restricting jaw movement. Wear of composite restorations in particular
adversely affects their esthetics. An increased amount of staining and loss of gloss is
associated with composite wear surfaces.
Generally, increased filler volumetric percentage (filler loading) improves the
physical and mechanical properties of RBC. Most filler particles are silicon dioxide
based and are either: crystalline silica--quartz; silica with metals--silicate glass; or
amorphous silica--colloidal or fumed silica. Fillers vary in size from a distribution that
averages less than 0.1 um to a distribution that averages 10 to 100 um [31]. Wear
resistance of composites improved with the addition of increased volume filler loading
and filler particle size distribution, unfortunately these newer materials became more
brittle, increasing the occurrence of bulk fractures [28]. A fracture within the body of
restorations and at the margins is a major failure mechanism of posterior composites. The
fracture related material properties, such as fracture resistance, elasticity, and the
marginal degradation of materials under stress have usually been evaluated by measuring
flexural strength, flexural modulus and fracture toughness of the developing materials
[32]. The presence of filler particles in restorative materials substantially increases the
![Page 23: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/23.jpg)
9
fracture toughness and the toughening mechanisms are assumed to be crack pinning,
crack deflection and matrix–filler interactions [33, 34].
Resin-based composites mechanical properties are dependent upon their
microstructure and composition. The microstructural characteristics involve the
distribution of filler particles in the monomer matrix, the morphology of these filler
particles and the presence of pre-existing cracks and voids. The inorganic filler content
and bond to the monomer matrix are most significant factors improving the mechanical
properties of resin-based composites [35]. Mechanical properties of the composite resin
increase with greater filler volume fraction while polymerization shrinkage decreases
[25]. Smaller filler particles have a more pronounced effect on strength than larger
particles at the same volume fraction [36]. Kim et al. observed a significant influence of
the filler rate and morphology on the flexural strength and modulus, microhardness and
fracture toughness of the composites resin [37]. Ikejima et al reported that the increase in
mechanical properties stopped when the filler load was 50%/vol [36].
Filler-matrix interfacial bonding that is achieved by silane coupling agent, is
another contributing factor in increasing mechanical properties of commercially produced
composites. Silane bonds the fillers to the matrix. Silanization of silica filler particles is a
well established method for increasing the silica filler-matrix interfacial bonding [27].
Vallittu [38] studied the influence of 2 silane compounds on the adhesion between
denture base acrylic and different types of fiber, including glass fibers. The silanized
glass fibers used for reinforcement markedly increased fracture resistance. In another
study, the importance of filler silanation was clearly demonstrated, as flexural strength,
flexural modulus and shear strength of the composites with silanated fillers were
![Page 24: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/24.jpg)
10
significantly higher than those of the composites with un-silanated fillers [36]. The
incorporation of nanometric sized filler particles in hybrid composites and even the
introduction of exclusively nanofilled composites are the most recent advances in filler
technology. Characteristically, these filler particles, due to their small size and rounded
shape, expose a high surface area and require, as a consequence, a higher amount of
silane. Musanje and Ferracane reported that the incorporation of silanized nanofiller
particles significantly increased abrasion and attrition wear resistance of an experimental
hybrid composite [27]. The same authors also reported that silanized nanometric filler
particles are capable of increasing the flexural strength and microhardness of composites.
All commercial composites have limitations either they have significant strength
or poor esthetics and lack gloss retention. Gloss is a physical property that is used to
describe the reflectivity of the composite surface. Reflectivity gives RBCs a more life
like esthetic appearance and is achieved by polishing the restoration. The polish of a resin
composite surface is related to the intrinsic properties of the material as well as the
finishing/polishing procedures used. With heterogeneous materials, such as composite
resins, smoothness of restorations is influenced by the filler size (macrofill, microfill,
microhybride, nanofill, and nanocluster filler), type of filler (silica or zirconica/silica) and
the filler arrangement.
Nanoparticles improve mechanical properties of materials. In dentistry, posterior
restorations (fillings) require resin composites with high mechanical properties while
anterior restorations where less bite force is exerted require resin composites with
superior esthetics and polish retention. Due to the reduced dimension of the particles and
a wide size distribution, an increased filler load can be achieved which reduces
![Page 25: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/25.jpg)
11
polymerization shrinkage while increasing the mechanical properties [39]. Small filler
particles improve the optical properties of resin composites because their diameter is less
than the wavelength of visible light (0.4-0.8 µm), resulting in the human’s eye inability to
detect the particles making the composite appear smoother [40].
The wear resistance of composite resins is significantly improved with decreased
average filler particle size and with increased filler loading [41]. Higher wear rates are
related to the larger filler particles in the composite materials [42]. Therefore, having
high filler content with small average filler size has been a method to produce composite
resins for posterior restorations, which need an adequate strength and wear resistance to
withstand the mastication forces, especially in highly stressed fillings [43]. The fillers
themselves, the filler load level and the filler–matrix-interactions have a greater influence
on fracture parameter of dental composites than the structure of the organic matrix. The
average filler size and the filler volume greatly affect the wear properties of the
composite materials.
Fiber reinforcement has been successfully used in dentistry for indications where
polymers have performed well, such as complete dentures and provisional restorations
[44]. Incorporation of fiber into dental polymers has been shown to enhance mechanical
properties [45-48]. Fiber reinforcement of polymers increases modulus of elasticity and
toughness via “modulus transfer”. Modulus transfer generally involves high elastic
modulus fibers in a lower elastic modulus matrix. A stress applied to the composite is
“transferred” from the matrix to the fibers. This transfer requires a reasonable level of
bond or friction between the fibers and matrix.
![Page 26: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/26.jpg)
12
Several factors control the degree of toughening that can be achieved by modulus
transfer: difference in modulus between the fiber and the matrix, strength of the fibers,
volume fraction of the fibers and architecture of the fiber contribution, length of the
fibers and interfacial bond between the fibers and matrix. The volume fraction of fibers
that can be successfully incorporated into a matrix affects the toughness and strength
achieved in that composite. Large volume is desirable as long as the fibers don’t interact
in such a way that they are damaged and lose strength. The resin impregnation is more
difficult at higher volume fractions (fiber volume fraction higher than 50%); while the
fiber distribution is less uniform at low-volume fractions [49]. Unidirectional fibers
provide toughening and strengthening only in the direction parallel to the fibers (one
dimensional architecture). Strength and toughening in the other directions are no better
than for the matrix. Such composites often fail in interlaminar shear rather than in
tension. To increase the resistance to shear failure, fibers are built into the composite
additional directions. Multidirectional architectures result in a decreased number of
fibers in any angle direction, so that the strength in the strongest direction is not as high
as for unidirectional fibers. However, the strength in the minimum direction is increased
for three-dimensional and higher composites to yield improved resistance to failure by
interlaminar shear mode.
Fiber length also affects the toughening and strengthening capability of fibers in a
composite. Modulus transfer can occur with shorter “chopped” fibers, but achieving a
controlled architecture or distribution of chopped fibers is difficult. The minimum length
of fiber that will yield modulus transfer depends on the relative moduli of the fiber and
matrix and on the degree of bonding between the fiber and matrix. Fiber diameter also
![Page 27: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/27.jpg)
13
found to have an influence in reinforcement. Griffith recorded a strength value of
approximately 100 MPa for bulk glass, but as he drew the fibers to smaller diameters,
their strength increased dramatically [50].
Ongoing research designed to reinforce composites has shown that the addition of
nanofillers in dental resins leads to enhanced wear resistance, improvement in mechanical
properties and polymerization mechanics. In addition, a noticeable improvement in the
polishabilty and surface gloss of these materials has been observed after nanofiller
reinforcement [51]. The nanofillers used typically are silica and zirconia nanomers (20
nm) and nanoclusters (3 - 5 µm) [52]. While these nanofilled hybrid materials have
shown improvement in mechanical properties, they rarely show effective crack resistance
[52]. This current study employs reinforcement of silica nanofibers in dental resins.
Nanofibers are polymeric or ceramic fibers having diameters ranging from 50 - 500 nm
by virtue of which they have a high surface area and possess many desirable properties
for reinforcement of polymers [53]. Along with their usage in advanced applications such
as bone and tissue scaffolds, drug delivery and catalyst enzyme carriers, nanofibers have
also been used for reinforcing other thermosetting resins namely epoxy and elastomers
such as rubber [54]. Kenig et al. have reported that micron scaled glass fibers and
nanofibers made of nylon 6, polyvinyl alcohol and Poly-L-Lactic acid reinforce dental
composites and have increased the fracture resistance of bis-GMA based composites [55,
56].
Short and networked carbon fibers have been used experimentally to increase
mechanical properties of resin composites. However carbon whiskers are difficult to bond
to the resin matrix. Xu et al. demonstrated that whiskers mixed into composite without
![Page 28: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/28.jpg)
14
silica particles became entangled and dispersion in the matrix was difficult [26]. In
addition, fusing silica particles onto the whiskers enhanced the whisker silanization and
its bonding to the resin matrix indicating whiskers cannot be silanated, furthermore,
whiskers impart a dark black color to the composite making it unaesthetic limiting patient
acceptance.
Recently, silica nanofibers have been successfully processed and offer a
promising reinforcement alternative to polymeric fibers because of the improved bonding
between silica and the resin matrix that can be achieved using a silane-based coupling
agent [57, 58]. Silica-filled composites also have the added advantage of improved
esthetics due to a similar refractive index to tooth.
In this study, after incorporating silica nanofibers (SNF) into a flowable
composite resin, the mechanical material properties of this formulation were measured
and compared to the unfilled flowable resin and commercially available highly filled
flowable composite resin.
The organization of this thesis is as follows. A description of objectives,
three specific aims of this research, null hypothesis is followed by the summary of
relevant literature and a background to the challenges encountered in current resin-based
dental restorative materials. The Materials and Methods follow the review section and
describe the experimental design, materials used, processing method, testing, and
characterization techniques employed in this study. The Conclusion highlights major
outcomes, practical implications, and limitations of this work.
![Page 29: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/29.jpg)
15
2. OBJECTIVES
The objective of this study was to fabricate silica nanofibers and blend them with
commercially available resin monomer to form highly reinforced direct filling flowable
composite resin with improved mechanical and physical properties. The three specific
aims of this study are as follows.
Silica nanofibers (SNF) fabrication, heat treatment and characterization of SNF
using scanning electron microscopy (SEM), Fourier-transform infrared (FTIR)
spectroscopy and X-Ray diffraction (XRD).
Surface treatment of nanofibers and incorporation of nanofibers in resin matrix
in different filler loads.
Testing and compare the mechanical and physical properties of the
experimental composite groups produced by adding different percentages of SNF
filler loads.
![Page 30: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/30.jpg)
16
3. NULL HYPOTHESIS
No difference will be observed in the mechanical and physical properties of
flowable composites produced by adding different filler load, compared with unfilled
composite resin and highly filled flowable composite resin.
![Page 31: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/31.jpg)
17
4. LITERATURE REVIEW
Organization of this section is as follows: background information regarding
dental diseases and need for a dental restoration, followed by a detailed review of the
dental composite resins composition, their clinical benefits, advantages and
disadvantages as well as challenges encountered by clinicians and manufacturers in
optimizing their handling characteristics and mechanical properties. The different types
of filler reinforcements used in dental composites and the benefits of each filler
reinforcements on basis of size and shape are discussed. Based on information gathered
from literature review and the available techniques, materials selection and methods of
silica nanofiber fabrication as a means of reinforcement are then studied, and an
experimental design is prepared and presented in sections 5 through 6.
4.1 Dental Caries and Restorative materials
According to the survey done by National Institute of Dental and Craniofacial
Research, dental caries is one of the most common chronic diseases in children [2].
Dental caries is defined as a destructive process causing decalcification of mineralized
tissues of the tooth, i.e enamel, dentin and cementum and results in cavitation of tooth.
Dental caries occurs when acid releasing bacteria colonize the tooth surface.
Streptococcus mutans and S. sobrinus are cariogenic bacteria that are part of the normal
flora of the oral cavity [59] and these microorganisms can be isolated from the plaque
![Page 32: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/32.jpg)
18
surrounding the dentition. Normal pH of saliva is in the range of 6.5 to 7.4. However,
demineralization of enamel begins with increase in concentration of acid released, and
the saliva attains a pH of 5.5 or less. These sequences of events can be observed soon
after the consumption of a carbohydrate rich meal, which are easily fermented by bacteria
present in saliva. Inadequate or poor oral hygiene allows Streptococcus mutans and other
cariogenic bacteria to multiply and colonize the tooth. These bacteria secrete lactic acid
as a byproduct after carbohydrate metabolism, creating a surface demineralization which
further results in a cavity, if not arrested results in pulpal inflammation and periapical
pathology with loss of tooth vitality. Once the caries has established in the tooth
structure, removal of the carious tooth structure followed by a dental restoration can
prevent its further spread. A timely intervention to restore the weakened tooth back to its
structure and function prevents the onset of new lesions in contacting teeth in the
opposing as well as same arch [58]. An ideal dental restorative material should have
properties similar to tooth and would be esthetically acceptable, biocompatible, wear
resistant, fracture and fatigue resistant [58]. With the development of awareness among
people towards oral hygiene and measures such as better health care, water and milk
fluoridation, and improvement in the diet of developed countries have also reduced caries
prevalence [2].
4.2 Dental Composites
Dental composite resins were first introduced commercially in 1962. These are tooth
colored restorative materials, and are available in various shades and translucencies to
match natural tooth color. Additionally, they can be bonded to the tooth, limiting the
amount of tooth preparation required in metallic restorations and thereby conserving
![Page 33: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/33.jpg)
19
healthy tooth structure. Bond between the dental composite resin and tooth structure also
helps in distributing stresses generated during mastication more uniformly which further
supports the remaining weakened tooth structure [58].
A dental composite is commonly composed of fillers like quartz, silica, glass
fillers, organic resin and photoinitiators [59, 60]. The resin matrix is typically composed
of bis-GMA (bis-phenol A-glycidyldimethacrylate), Urethane dimethacrylate (UDMA),
bis(methacryloyloxymethyl)tricyclodecane. Bis-GMA is the most commonly used resin
in majority of the dental composite resins marketed today, since it shows a relatively
small percentage of polymerization shrinkage and stress post polymerization. However,
the structure of bis-GMA, as seen in Figure 4 (a), makes it extremely viscous, which
further reduces the degree of potential reinforcement to the matrix for improving its
stiffness.
To reduce the viscosity of bis-GMA and to improve the handling properties of
dental composite, a low molecular weight monomer TEGDMA
(tetraethylglycidylmethacrylate), (Figure 4(b)), is blended with bis-GMA in varying
percentages. Unfortunately, addition of TEGDMA results in increased polymerization
shrinkage of the system.
![Page 34: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/34.jpg)
20
Fig. 4. Chemical structures of (a) bis-GMA and (b) TEGDMA
Increased polymerization shrinkage creates a corresponding stress at the marginal
interface, leading to de-bonding of the restoration, marginal staining and secondary caries
in the marginal gap. Hence, a correct ratio of the percentages of the competing resins is
critical to the final properties of the composite.
Addition of fillers in resin reduces polymerization shrinkage by substitution of the
resin matrix by volume. Additionally, they also improve required mechanical properties
such as fracture toughness, flexural strength, modulus, wear resistance and decrease
water sorption [8]. There are various inorganic fillers used in dental composites which are
typically glass, quartz, barium silicate, zirconium silicate, barium, strontium etc. A small
percentage (5 – 10%) of pre-polymerized resin commonly referred to as “organic” filler
is also added in microfilled composites. The fillers are treated with silane coupling agent
to establish a chemical bond between fillers and with the resin matrix and to improve
dispersion of fillers within resin matrix. Literature shows that the interfacial treatment of
inorganic fillers with a silane coupling agent affects the mechanical properties of the
resulting composite [61, 62]. Further studies have shown that improved mechanical
properties were more significant with silane treated fiber reinforced composites compared
with silane treated particles reinforced composites [63].
![Page 35: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/35.jpg)
21
Silane coupling agents are mostly organo-silane compounds with two different
reactive groups bonded to the silicon atom as seen in Figure 5. While at one end, for
example the hydroxyl group, reacts with the silica in inorganic fillers such as glass to
form a chemical bond; the reactive groups at the other end (e.g. vinyl, epoxy, methacryl,
amino and mercapto groups) bond with various kinds of organic materials or synthetic
resins to form a chemical bond. Figure 6 shows a commonly used coupling agent in
dental composites is γ-mercaptopropyl-trimethoxysilane.
Fig. 5. Represents the silicon bridging between the polymer matrix and inorganic fillers
Fig. 6. Chemical structure of γ-mercaptopropyl-trimethoxysilane
![Page 36: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/36.jpg)
22
Studies had also shown that silane treatment of nano-filled composites affects
thermal characteristics of dental composites [64]. A shift in glass transition temperature
(Tg) of the composite is observed with reinforcement of silane treated fillers. This holds
an important implication to the performance of dental restorative materials, since on an
average the mouth undergoes a temperature variation from 5.6 to 58.5 °C in a 24 h period
[65]. Hence, the application of the coupling agent is vital to controlling the properties of
the composite. A detailed discussion of the varieties of fillers used in dental composites
is presented in Section 4.2.1 through 4.2.3.
4.2.1 Based on Dimension.
Dental composites are classified on the basis of type of fillers they contain and
viscosity (Table 2). Traditional composites, with filler size of 20 – 50 µm, produced
restorations with poor polishabilty, high surface roughness and inadequate gloss retention
[66, 67]. These defects resulted when the surrounding resin matrix wore under
masticatory loads exposing large hard fillers, which ultimately protruded past the matrix.
Microfilled composites with micron-sized colloidal silica produced a smooth surface
finish but had reduced properties compared to macrofilled composites [68].
Table 1. Filler loading and filler size distribution in different composite systems [69].
Materials Filler Size (μm) Filler wt %
Traditional 1-50 60-70
Hybrid 0.4-1 60-65
Nanocomposite 0.002-0.075 78-80
Microfilled 0.04-0.4 32-50
Packable 0.04, 0.2-20 59-80
Flowable 0.6-1.0 42-62
![Page 37: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/37.jpg)
23
Hybrid composites containing multiscaled “organic” (pre-polymerized resin) and
inorganic fillers was introduced later in the market and these materials offered a
compromise between esthetics and mechanical properties. Addition of multiscaled fillers
(Figure 7) resulted in increased filler loading and also reduced polymerization shrinkage.
With advancements in technology and the known benefits of the novel properties of
nanosized fillers, nano-filled dental resins were introduced. Now a days, majority of
posterior composite restorations are restored using nano-hybrids.
Fig. 7. Schematic depicting the augmentation in packing fraction with different sizes of fillers.
4.2.2 Based on Material.
With the increasing interest of patients towards esthetic dentistry, dental
composite should meet the demands of today’s restorative needs, and hence, dental
composites need to match tooth color and translucency, necessitating an optical index
close to 1.5. In addition to the improved esthetics achieved, if the refractive index of
fillers matches that of the resin matrix, an increased depth of cure occurs due to enhanced
light transmittance with light activated systems. As mentioned earlier, fillers such as
strontium, barium, slass, silica, quartz, zirconia, borosilicate glass and pre-polymerized
resin, are commonly in dental composites. Today, colloidal silica and pre-polymerized
resin are the main fillers in the commercially available hybrid composites.
![Page 38: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/38.jpg)
24
4.2.3 Based on Geometry.
Fillers of various shapes like spherical or irregular shaped depending on the
manufacturing method are used commercially. Each shape have their own significance
like spherical fillers provide a tighter packing [70], whereas, fillers with sharp
angulations can act as stress concentration sites, reducing fracture toughness of the
composite [71]. In order to overcome stress concentration, carbon whiskers possessing a
fibrous geometry were used to reinforce dental resins [72]. These long carbon fibers
improved fracture toughness and modulus of the resin, and the long fibers improved the
fracture toughness of the components [71, 73 - 75]. Glass fibers have also been used in
perform inserts which are polymerized resin matrices containing embedded glass fibers
[73]. The purpose behind this approach was to avoid challenges like fiber pullouts during
polishing and wear and also addition of pre-cured composite in the restoration helps to
reduce shrinkage. However, carbon whiskers imparted a black color to the composite,
making it unesthetic, thus limiting patient acceptance, while glass fibers disintegrated
from the matrix when subject to abrasion. Recently, micron-sized short fibers and
nanofibers made of polymeric material have been used for improving composite strength
and have shown promising results [55, 54]. Kenig et al. showed that addition of 5 %
(w/w) neat nylon 6 nanofibers into bis-GMA/TEGDMA (50/50 mass ratio) improved
work-of-fracture, flexural strength and elastic modulus compare to unfilled formulations.
4.3 Fabrication of Nanofibers
Since silica has shown many favorable properties and can be bonded to the resin
matrix, we began an investigation into the various available sources and methods for
fabricating silica nanofibers. Several techniques can be used for silica nanofibers
![Page 39: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/39.jpg)
25
fabrication. Silica nanofibers can be fabricated using techniques such as drawing,
template synthesis, temperature-induced phase separation, molecular self assembly, and
electrospinning [76].
4.4.1 Drawing
Polymeric micro/nanofibers may be formed by drawing and solidification of a viscous
liquid polymer solution, which is pumped through a glass micropipette or may be
extracted using instruments as seen in Figure 8. This process facilitates the formation of
networks of suspended fibers having amorphous internal structures. Using this method,
individual fiber diameters up to 50 nm may be produced. The fiber drawing method,
however, is limited by time, since the viscosity of the polymer solution increases while
the volume of solution available in every drop decreases. This affects the quality and
reproducibility of the fiber diameters [77, 78].
Fig. 8. Schematic of continuously drawn array of fibers on a silicon substrate adapted from the work done by Nain et al [77].
![Page 40: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/40.jpg)
26
4.4.2 Molecular Self–Assembly
Molecular self–assembly involves the building of nano-sized structures such as
colloids, nanotubes, and wires through chemical synthesis [79]. However, it requires
complex procedures and techniques, and the diameter formed is in tens of nanometers.
Such dimensions are too small to be effective reinforcement for improving the toughness
of materials.
4.4.3 Template Synthesis
Template synthesis is a popular method for fabricating nanowires of conductive
polymers, metals and semiconductors. Figure 9 shows the process of obtaining
nanowires, by filling a porous template containing a large number of straight cylindrical
uniform-sized holes. Two popular methods for filling the template are either by high
pressure injection from a melt or by electrochemical deposition [80]. Fibrils as fine as 3
nm have been fabricated using this method; however, the overall fiber diameter
distribution obtained is narrow [81]. Since the targeted diameter desired for the silica
nanofibers is in range of 150 – 450 nm in order to achieve a high volume fraction, a
method for fabricating nanofibers is required that can deliver fibers in a range of
diameters.
Fig.9. Template Synthesis of Nanowire/Nanotube Heterostructures [82]
![Page 41: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/41.jpg)
27
4.4.4 Phase Separation
Phase separation refers to the process of thermodynamic separation of polymer solution
into polymer-rich/poor layers. It has been used effectively in the production of scaffolds,
but has a drawback of small production scales. This method is still currently in use for
production of biological scaffolds.
4.4.5 Electrospinning
Electrospinning is a popular technique to fabricate synthetic or biological polymers and
ceramic nanofibers [83-90]. Originally, this technique was employed to make tissue
scaffolds for bone and cartilage, but high strength composites, nanoporous membranes
for filtration, drug delivery and enzyme carriers are also fabricated using the same
methodology. The process has been in use for over 80 years and was first patented by
Formhals in 1934. He designed an apparatus and electrospun cellulose acetate using an
acetone/alcohol solution as the solvent. However, due to a close proximity of the
collector to the charged polymer solution, the solvent did not evaporate completely.
Later, a better understanding of the process helped researchers develop a more useful
technique to produce continuous fibers whose diameters can be controlled by optimizing
the experimental parameters.
The electrospinning apparatus, as depicted in Figure 10, uses a high voltage
source, a syringe filled with polymer solution, and a grounded metallic collector. The
solution to be spun is pumped at a low rate through the needle, forming a semi-spherical
droplet shape at the needle tip. Applying high voltage to the needle introduces a charge in
the solution. When the electrostatic forces become large enough to repel the surface
tension, an elongated droplet at the tip known as the Taylor’s cone is formed and a jet is
![Page 42: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/42.jpg)
28
ejected. Any instability in the electric field causes the jet to take a whipping motion
which helps to stretch the fibers and evaporate any solvent [91].
Fig. 10. Schematic of the electrospinning apparatus [84]
The fibers can be electrospun either from melt or by the sol-gel technique. The
sol-gel technique for the fabrication of silica fibers is the most commonly used approach,
since it offers a high yield of silicon dioxide. Preference for the sol-gel technique to
prepare the precursor solution also stems from the ease with which this process can be
adapted for nanotechnology, by controlling the scale of production in contrast to the
traditional melt-derived approach. The sol-gel approach allows for fiber diameters from
50 – 1000 nm, while the melt approach restricts the fibers in the 10 – 100 nm range [92].
In addition, the sol-gel approach yields a higher silica content per mole [93]. Once the sol
is prepared, a binder polymer is incorporated to facilitate the charging of the solution and
formation of smooth fibers.
The quality of fibers formed and the ability to spin uniform fibers with bead-free
![Page 43: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/43.jpg)
29
morphology depends upon factors such as applied voltage, needle tip to collector
distance, solution pump rate, solution concentration, viscosity and surface tension.
4.4.5.1 Applied voltage.
The morphology of the fibers is controlled by voltage. Varying the applied
electric field can alter the fiber diameter. Both low and excessively high field
strengths can lead to bead defects or even failure in jet formation, which leads to
an interruption in fiber production. At low voltages, the Taylor cone forms in the
tip of the pendent drop; however, as the voltage is increased the volume of the
drop decreases until only the Taylor cone remains formed at the end of the
capillary. Low voltages provoke the drop to oscillate with time [94]. At too low
voltages, gravitational forces dictate the distortion in shape of the drop, ultimately
resulting in dripping of the pendent drop. If the voltage is too high, the drop
becomes smaller and the beginning of the jet shifts to the edge of the capillary’s
orifice and finally stops [94]. After a certain minimum voltage is attained, fiber
formation starts; low voltages yield beaded fibers and higher voltages yield
smooth fibers. Nonetheless, increasing the voltage further will also produce
beaded fibers. This increase in the density of beaded fibers is a result of the
inability of a stable Taylor cone to form at high voltages and the consequent
formation of an unstable liquid jet [83].The average fiber diameter increases as
the voltage is increased [83]. This probably happens due to a higher mass flow
caused by the increased field strength.
![Page 44: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/44.jpg)
30
4.4.5.2 Solution pump rate.
Polymer flow rate has an effect on fiber size, which can influence fiber porosity
and fiber shape. It has been postulated that the polymer’s flow should be enough
to replace the material ejected in the fiber jet. Generally, fiber diameter increases
as the feeding rate increases. The enlarged diameter is due to the increased mass
flow rate of the polymer solution. A mathematical model developed by Fridrick et
al. validated that increasing the flow rate produces a six-fold variation in fiber
diameter [95]. Another anomaly associated with high flow rates is the appearance
of beads on the fibers which can be attributed to insufficient solvent evaporation
before reaching the collector plate. Hollow tubes or ribbon like structures are also
seen since sufficient time is available only for the outer surface to dry and
solidify, leaving the inner core hollow. A collapse of these tubes later results in
the band like flat ribbons being formed.
4.4.5.3 Tip to collector distance.
By adjusting the distance between the tip of the needle and collector plate, fiber
diameter can be altered. An increase in this distance results in smaller diameter of
fibers and reduction in appearance of beaded structures, since a larger distance
allows for increased whipping motion of the polymer jet and thinning of the fibers
[84]. Additionally, more time is available for the complete evaporation of the
solvents in the solution before deposition of the fibers. The optimum distance
however has to be maintained since a larger distance results in the gravitational
forces overcoming the voltage.
![Page 45: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/45.jpg)
31
4.4.5.4 Viscosity of precursor solution.
The solution should have a high enough polymer concentration to allow chain
entanglements, yet low enough so that too high a viscosity does not prevent fiber
formation [96].The instability in the jet driven by its surface tension is the cause
for the formation of beads [97]. At a higher concentration of solution, the
entangled polymeric molecules need longer time to diffuse and relax [96, 98]. A
certain amount of entanglements (elasticity) are however required to form
uniform fibers. Hence, there is a fine interplay between viscosity and fiber
formation. When the polymer concentration is too low (low elasticity), the jet
breaks up into droplets and if it is too viscous, fibers will not be formed.
4.4.5.5 Surface tension
Surface tension is a result of the interplay between the solvent properties and the
polymer concentration. Reduction in the surface tension of the polymer solution
limits bead formation. Hence the choice of the solvent/polymer combination is
critical to the spinnability of the solution and proper fiber formation [94].
Based on the above parameters the experimental design of the study was developed as
described in the following section.
![Page 46: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/46.jpg)
32
5. MATERIALS
This study was divided into 3 phases - nanofiber fabrication, preparation of
experimental material and experimental composite testing. The nanofibers used in this
study were fabricated by the process of electrospinning. Following fibers fabrication,
fibers were surface treated with silane couplining agent before being incorporated into a
base resin, which also contained a light activated curing agent. The following section
provides a description of the materials that were employed in this study.
5.1 Electrospinning solution
Electrospinning involves a sol-gel technique for the preparation of a sol, which is
blend with a polymer. A set of sol-precursors are mixed in a specific ratio and allowed to
mature for 2 hours. A detail of the materials used for preparing the electrospinning
solution is presented.
5.1.1 Sol Precursors
Three precursors were used for the electrospinning solution: tetra (ethyl
orthosilicate), ethanol, and hydrochloric acid. Reagent-grade tetra (ethyl orthosilicate)
(TEOS) with 98% purity was obtained from Sigma-Aldrich, Inc. TEOS is the ethyl ester
of orthosilicic acid, Si(OH)4 that is classified as an organo-metallic compound, i.e., it has
![Page 47: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/47.jpg)
33
an organic ligand attached to a metalloid atom as seen in Figure 11 [99]. The reactivity of
the Si-OR bonds makes it a widely used cross- linking agent in silicone polymers. This
chemical compound Si(OC2H5)4 was used in sol-gel synthesis of silicon dioxide through
a hydrolysis reaction, as depicted in Equation 1, followed by a condensation reaction with
water [100].
Si(OC2H5)4 + 2H2O SiO2 + 4C2H5OH
Fig. 11. Chemical structure of tetra (ethyl orthosilicate) (TEOS)
Laboratory grade ethanol (C2H5OH) and 98 % HCl were obtained from Fisher
Scientific, Pittsburgh, PA. Ethanol is a known organic solvent and is commonly used in
the manufacture of silica by the sol-gel method. HCl was used to catalyze the sol-gel
hydrolysis.
5.1.2 Binder Polymer
Poly (vinyl pyrrolidone) (PVP) is a synthetic polymer, which was used in the
electrospinning of silica nanofibers. Figure 12 shows the chemical structure of PVP. The
molecule acted as a binder and facilitated the formation of nanofibers in the
electrospinning process. The ease of solubility of the polymer in water, and other polar
[Equation 1]
![Page 48: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/48.jpg)
34
solvents accounts for its good wetting properties. For this study, PVP was purchased
from Sigma-Aldrich Inc., with an average molecular weight of 55,000 and was used as
received.
Fig. 12. Molecular structure of Polyvinylpyrrolidone (PVP)
5.2 Experimental Groups
The experimental groups were designed based on the matrix, filler type and
percentage of filler content as seen in Table 2. For all resin groups, the same bis-
GMA/TEGDMA ratio was maintained. Light activated initiators were added to render the
experimental resins photo-polymerizable.
Groups Matrix Filler type Filler wt %
Clear resin (Negative Control)
Bis-GMA/ TEGDMA - -
Experimental 1 (20wt%)
Bis-GMA/ TEGDMA Silica nanofibers 20
Experimental 2 (35.8wt%)
Bis-GMA/ TEGDMA Silica nanofibers 35.8
Experimental 3 (20wt% H)
Bis-GMA/ TEGDMA Silica nanofibers & nanoparticles
20 (1:1)
PermaFlo (Positive Control)
Bis-GMA/ TEGDMA Macroparticles 68
Table 2. Represents 3 experimental groups with different filler loads (wt%) and Clear Resin and PermaFlo (Negetive and positive control respectively).
![Page 49: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/49.jpg)
35
6. METHODS
The first half of the study was dedicated towards the development of SNF. The
electrospinning procedure, subsequent heat treatment procedures, and a detailed
description of the characterization methodology employed for determining the quality of
the SNF are provided in this section. The second half of the study was devoted to the
characterization of the experimental composites. In this segment, the procedures for
determining fracture toughness, flexural strength, three body wear, viscoelastic
properties, polymerization shrinkage, degree of conversion and gloss of the bis-GMA
resin-based experimental composite groups are explained.
6.1 Fabrication of SNF
6.1.1 Preparation of Silica Sol
Silicon dioxide was synthesized using an acid catalyzed sol-gel process in this study [56,
101, 102]. The sol was prepared using TEOS and ethanol in acidified water [57]. Figure
13 shows the acidic catalysis of the sol, initiated by the addition of HCl, which is known
to produce linear structures in contrast to basic catalysis, which yields branched
structures [57, 99].
The sol was allowed to stir continuously on a heated stirrer plate and cooled to
room temperature. This maturation procedure was used to consolidate the linear structure
of the silica molecules and to increase the viscosity of the sol.
![Page 50: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/50.jpg)
36
Fig. 13. Depiction of technique for preparing the silica sol. HCl is added drop-by-drop to the ethanol, TEOS and distilled water blend, followed by a heat treatment.
6.1.2 Electrospinning
A horizontal electrospinning apparatus was used for fabricating the PVP-SNF
(silica nanofiber) mats as reviewed in the literature represented in Figure 14. PVP powder
was dissolved in silica-sol and ethanol under gentle agitation to obtain a solution with
20% wt/vol concentration. This mixture was allowed to stir for 2 h to obtain an optimum
viscosity for electrospinning. The resulting solution was transferred into a 5 ml syringe
with a 25½-gauge needle and electrospun at a voltage of 18 kV using a high voltage
source (M826, Gamma High-Voltage Research, Ormond Beach, FL). The feeding rate of
the polymer solution was set to 0.5 ml/h using a syringe pump (KD Scientific, Holliston,
MA). The polymer solution jet ejected from the tip of the needle was collected at room
temperature on a grounded rotating collector (5000 rpm) covered with aluminum sheet at
a distance of approximately 20 cm. Random, non-woven mats were obtained.
![Page 51: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/51.jpg)
37
Fig. 14. Schematic of the electrospinning apparatus consisting of a syringe with polymer solution, high voltage source attached to the needle tip and a grounded rotating aluminium collector.
6.1.3 Calcination
Calcination is a thermal treatment done to bring about a thermal decomposition,
phase transition, or removal of a volatile fraction. In order to remove the PVP binder
molecules from the electrospun PVP-SNF mats, the mats were calcined. The mats were
heated in a furnace (ProPress 100, Whip Mix Corporation, USA) was maintained for 2
hours. The calcined mats were allowed slowly to cool to room temperature. Non-woven
silica nanofiber mats (SNF-C), devoid of any binder polymer, were obtained.
Rotating Collector
![Page 52: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/52.jpg)
38
6.2 Characterization of nanofibers
6.2.1 Scanning Electron Microscope (SEM)
SEM (FEI Company QuantaTM
650 FEG) was used for determining fiber
morphology of uncalcinated silica nanofiber (PVP-SNF) and calcinated silica nanofiber
(SNF-C) mats. Samples were sputter-coated with Au-Pd under vacuum and examined at
an accelerating voltage of 20 kV at the upper stage position. Fiber diameter
measurements were calculated using SEM micrographs of both PVP–SNF and SNF-C
mats by Image Analyzer software (Image-J, Image Processing and Analysis in JAVA). A
hundred counts per micrograph were made.
6.2.2 Fourier Transform Infrared Spectroscopy (FTIR)
Infrared spectroscopy (NICOLET 4700 Thermo Electron Corporations, USA) was
used to analyze the silica nanofiber before calcification (PVP-SNF) and after calcification
(SNF-C) in attenuated total reflectance (ATR) mode. Each specimen was configured to
have 32 scans per minute at a resolution of 4 cm-1. The resulting spectra were used to
determine the molecular structure and estimate the amount of PVP present in the sample
before and after heat treatment.
6.2.3 X-Ray Diffraction (XRD)
X-Ray diffraction (Siemens D500 Diffractometer) was used to characterize the
crystallographic structure of calcinated silica fibers. This technique is based on the elastic
scattering of X-rays from the electron clouds of the individual atoms in a system (Figure
15).
![Page 53: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/53.jpg)
39
Fig. 15. Diagrammatic representation of X-Ray Diffraction Technique [103]
A rotating X-ray generator (40 kW, 40 mA) with Cu Kα radiation (wavelength λ
= 1.54 A°) was used for XRD measurement. The XRD profiles were recorded from 0º to
60º at a scanning speed of 2º/min. The resulting diffraction pattern was used to
characterize the crystallographic structure of calcinated silica fibers.
6.3 Silanization of Fibers and Sample Preparation
A surface treatment to the SNF was done by Ultradent Products, Inc., (Salt Lake
City, Utah, USA). The purpose of surface treatment of SNF was to improve bonding
between the matrix and silica nanofibers. The silanated fibers were processed to powdery
consistency before incorporation into resin matrix.
![Page 54: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/54.jpg)
40
6.3.1 SNF Incorporation into Dental Resin
The silanized SNF were incorporated in photo-polymerizable bis-GMA/
TEGDMA matrix under high vacuum and shear mixing at Ultradent Products Inc (Salt
Lake City, Utah, USA). A filler loading of 20 wt% and 35.8 wt% of nanofibers was used
to prepare experimental group 1 and 2 respectively. A third experimental group was
prepared by incorporating a mixture of SNF and spherical silica filler particles (SFN)
(diameter 1µ) in ratio of 1:1 and filler load of 20 wt% using similar procedures and base
resin as the SNF group.
6.4 Characterization of Experimental Groups
6.4.1 Rheology (Visco-elastic property)
Rheological properties of all experimental resins were determined for the
assessment of their handling properties and their ability to adapt cavity walls during
restoration of cavity. Visco-elastic property was also determined to study the effect of
nanofiber incorporation on the viscosity of the uncured composite. All experimental
groups were tested using a parallel plate (diameter = 25 mm) fixture of the Rheometer
(AR 2000, TA Instruments, New Castle, Delaware USA). Figure 16 shows a
representation of the instrument fixture with the distance between the plates fixed at 0.5
mm. Strain sweeps employed 0.01-100.0% strain at a shear rate of 1.0 s-1. A frequency
sweep was performed at 25°C.
![Page 55: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/55.jpg)
41
Fig. 16. Specifications of a parallel plate rheometer in oscillatory mode
6.4.2. Gloss
Tooth-colored resin composites have been widely used because of their excellent
esthetic properties [104, 105]. Surface roughness, surface gloss, and color are among the
most important factors in the perceived visual effects of resin composite restorations
[106]. Gloss is an aspect of the visual perception of objects that is as important as color
when considering the psychological impact of products on a consumer. It has been
defined as 'The attribute of surfaces that causes them to have shiny or lustrous, metallic
appearance”. Five specimens (Dimensions 10x6x2 mm) per group were prepared. Each
specimen was cured for 20 seconds using 3M Elipar S10 ((Power Intensity: 1000-1100
mW/cm2), polished with SiC abrasive paper (320-600-1200-2000) under water spray for
1 minute each using a rotational polishing device (No 233-0-1997, Buehler Ltd,
Evantson, IL) followed by finishing with 0.05 µm alumina slurry and a polishing cloth.
Specimens were rinsed under water and ultrasonically cleaned in an ultrasonic unit
(Branson 1200) in distilled water for 5 min. Prepared specimens were stored in deionized
water for 24 hours at 37ºC before measurement of gloss. Gloss for all the experimental
![Page 56: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/56.jpg)
42
groups were measured by glossmeter (Rhopoint Nano-curve Glossmeter). This
instrument is based on ASTDM D 523 specification. Gloss was measured on a scale of 1
to 100 with a square measurement area of 2x2 mm and 60º geometry. One reading was
made, specimen rotated at 90º and another reading made. The mean of two readings was
recorded as gloss unit (GU) of a specimen.
6.4.3. Degree of Conversion (DC)
The percentage degree of conversion (DC) was calculated using spectra from a
FT-IR spectrometer (NICOLET 4700 Thermo Electron Corporations, USA) that used an
attenuated total reflectance crystal (ATR). The composite specimens were prepared with
dimensions (d=10mm, t=2mm). The specimens were light cured using 3M ESPE Elipar
S10 (Power Intensity: 1000-1100 mW/cm2), and stored at 37 °C for 24 h before testing.
For all experimental groups, spectra for uncured and cured (24 hours post cure) samples
were obtained using the FT-IR with the same operating parameters as mentioned in
section 6.2.2.
The degree of conversion of dental composites is the conversion of monomer to
polymer after curing and is measured in term of concentration of reacted double bonds as
a percentage of the total amount of methacrylate groups present in the unpolymerized
resin. Bis-GMA based resin systems consists of two very prominent absorbance peaks;
1638 cm-1 corresponding to C = C bonds stretching in the aliphatic ring and 1608 cm-1
corresponding to the C – C stretching vibrations of aromatic rings. Aromatic peak
intensity is considered as an internal standard and remains unaffected by double bond
conversion occurring during polymerization. The remaining double bonds for each
spectrum was determined by a comparison of the aliphatic C = C peaks with the standard.
![Page 57: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/57.jpg)
43
Equation 2 was used to calculate the DC [107, 108].
==
==
−∗=uncured
CCCC
curedCCCC
DC
aromatic
aromatic
aliphatic
aliphatic
1100
Where:
C = C Aliphatic corresponds to absorbance peak 1638 cm-1
C = C Aromatic corresponds to absorbance peak 1608 cm-1
6.4.4 Polymerization Shrinkage
Polymerization shrinkage represents difference in volume of a material before and
after curing and is measured as percent change in volume. Polymerization shrinkage was
determined using ACUVOL volumetric shrinkage analyzer (BISCO, Inc., Schaumburg,
IL) (figure 17). ACUVOL uses a video imaging technique to measure volumetric
shrinkage. Several other methods had been used in past to measure shrinkage such as
mercury dilatometry, water dilatometry, strain gauge, linear contraction, and density
measurements [109-114]. However, use of mercury in mercury dilatometry procedure
[115] raised health concerns which limit its use whereas, use of other procedures do not
possess the ease of operation that the ACUVOL provides. Additionally, the linear
contraction and density measurement methods are not applicable to all situations,
particularly specimens involving anisotropic structures.
Specimens of all experimental groups were placed on the pedestal in the
[Equation 2]
![Page 58: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/58.jpg)
44
ACUVOL chamber as small spheres and cured for 20 s after placing using 3M ESPE
Elipar S10 (Power Intensity: 1000-1100 mW/cm2). The shrinkage values were recorded
continuously for about 10 min after curing. The average of the values between 7 min and
10 min intervals was used as the final shrinkage value because these percent shrinkage
values were observed to be near-steady. Five readings were taken for each material. A
one-way ANOVA and Tukey/Krammer test was done to determine any difference
between the experimental groups tested.
Fig. 17. The Acuvol showing the rotating pedestal for sample placement and camera for real time imaging.
6.4.5 Three Body Wear Testing
The Alabama wear simulator, an in vitro model for wear measurement, was
employed for testing four experimental resin groups. In-vitro models have proved to be
useful tools in the measurement of wear of dental materials [116]. These in-vitro models
provide standardized testing conditions by controlling variables such as force, acidity of
the environment, exposure time, temperature, provides ease of studying wear at an
accelerated rate. However, the ability to simulate the biological condition of the oral
cavity in its entirety is the biggest drawback of in-vitro wear stimulators. The in-vitro
![Page 59: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/59.jpg)
45
dental wear simulators cited in dental literature consist of the Oregon Health Sciences
University Oral Wear Simulator (OHSU), University of Alabama at Birmingham Wear
Simulator, Zurich computer controlled masticator, BIOMAT wear simulator, ACTA wear
machine and Minnesota MTS wear simulator. The University of Alabama at Birmingham
wear simulator has been cited the most out of all the available systems [100].
The Alabama wear simulator consists of a stylus with replaceable tips (stainless
steel, ceramic or composite). Each stylus uses springs to generate a force of
approximately 75 N, which is calibrated separately for each stylus/sample pair. Studies
have shown that clinically relevant biting forces range from 20 – 120 N [100, 117].
Alabama wear stimulator design permits four samples to be mounted on brass holders
with acrylic that are fastened opposing the stylus.
The five experimental composite resin groups were tested for wear properties.
Figures 18 (a) through 18 (e), show the different steps in the preparation of the wear
samples. Samples (n=8) were prepared using cylindrical mold made of an impression
material with the dimensions of d = 10 mm and h = 4 mm, was used to prepare eight
composite samples for each material. The composite specimens was built up in 2
increments, 2 mm each and were light cured using 3M ESPE Elipar S10 curing light
(Power: 1000-1100 mW/cm2), for 20 seconds. The prepared specimens were stored in de-
ionized water at 37 °C for 24 h following which they were embedded in the center of
brass holders (d = 15 mm) using a self curing acrylic material. Specimens were wet
ground flat using 320, 600, 1200-grit SiC abrasive paper under water spray for 1 min
each, using a rotational polishing device (Model No: 233-0-1997, Buehler Ltd, Evanston,
IL, USA) followed by finishing with 0.05 µm alumina slurry and a polishing cloth. They
were rinsed under water and cleaned with an ultrasonic bath in distilled water for 5 min.
![Page 60: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/60.jpg)
46
Fig. 18. (a, c) Composite specimen build up incrementally using hand instruments, (b) light curing the final layer of the composite specimen under a glass slide, (d) mounted specimen (center) on brass holder, (e) polishing of the mounted specimens and (f) the Alabama wear simulator
The prepared specimens were then placed in the Alabama wear simulator, as
shown in Figure 18 (f). A load of 75 N was applied using stainless steel tips for 200,000
cycles. PMMA beads (d = 50 µm) were mixed with water (15 g beads for 9 g water) and
![Page 61: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/61.jpg)
47
made into a paste. Prepared paste was introduced between the specimens and the stylus as
a third body media. A non-contact 3D surface measurement instrument (PROSCAN
2000, Scantron Industrial Products, Ltd., Taunton, England) was used to scan the
specimens (figure 19). The volumetric wear and depth of wear of the materials was
determined using ProForm software (Scantron Industrial Products, Ltd., Taunton,
England). One-Way Anova and post-hoc Tukey’s Kramer test was used for data analysis.
Fig. 19. Proscan volumetric shrinkage machine with samples placed for scanning
6.4.6 Fracture Toughness and Flexural Strength
Fracture toughness specimens (n=10) of all five experimental groups were
prepared using a Teflon mold with dimensions of 25 × 2 × 2 mm, with a 1 mm notch at
12.5 mm (Figure 20). The specimens were light cured (3M ESPE Elipar S10) overlapping
previous cured areas on the exposed surfaces of the specimen for 20 s. Specimens were
stored in deionized water at 37ºC for 24 h and then fracture-tested using 3-point bend
technique on the Instron 5565 (Universal Testing Machines, Admet, Norwood, MA) at a
cross head speed of approximately 1 mm/min.
![Page 62: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/62.jpg)
48
Fig. 20. Specimen dimensions and applied loads in a fracture toughness test
The stress field around the notch in the specimens is described by term, KI (stress
intensity factor). The notch which is a representative of a crack, grows when the stress
field reaches to a critical value, i.e., at critical K, also known as KIC (fracture toughness).
Peak failure load was recorded for each experimental group, and KIC values were
calculated using Equation 3.
5.1
)(bw
xPLFK IC =
Where P = Fracture load
b = thickness of specimen
w = width of specimen
L = span of base;
F(x) = Constant; function of location and length of crack
Flexural strength specimens (n=10) were prepared using a Teflon mold with
dimensions of 25 × 2 × 2 mm. The specimens were light cured (3M ESPE Elipar S10) at
three overlapping areas on the exposed surfaces of the specimen for 20 s. The prepared
[Equation 3]
![Page 63: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/63.jpg)
49
specimens were stored in deionized water at room temperature for 24 h and then fracture-
tested using 3-point bend technique (Figure 21) on the Instron 5565 (Universal Testing
Machines, Admet, Norwood, MA) at a cross head speed of approximately 1 mm/s.
Fig. 21. Systematic representation of 3-point bend test.
Flexural strength under a load in a three-point bending test was measured by equation 4:
Where F = load (force) at the fracture point
L = length of the support span
b = width of specimen
d = thickness of specimen
A one way ANOVA and Tukey/Krammer tests were done to analyze the results of
both fracture toughness and flexural strength. Since the mechanical properties of the
prepared experimental composites are also a function of the filler dispersion in the
matrix, SEM images were taken of fracture toughness samples post fracture. The images
[Equation 4]
![Page 64: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/64.jpg)
50
were also taken to establish the role of the silane-bonding agent in improving fracture
toughness of these composites.
![Page 65: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/65.jpg)
51
7 RESULTS AND DISCUSSION
7.1 Characterization of Nanofibers
7.1.1 Scanning Electron Microscope (SEM)
First specific aim of this study was the fabrication of silica nanofibers and
characterization of fabricated silica nanofiber. Quality of the SNF was characterized
using SEM images. The images were used as an aid to check the presence of bead
formation while electrospinning and to measure diameter of fibers before and after
calcinations. SEM images (figure 22 (a,b)) showed no beading or droplet formation along
the fibers spun from a 20% wt/vol concentration. Increase in concentration of solution is
associated with increase in polymer entanglements which further leads to increased
viscoelasticity and decrease in bead/droplet formation. Droplet formation/electrospraying
can be observed when solutions of low molecular-weight polymers are used in the
presence of an electrical force of sufficiently high voltage. The resulting surface tension
favors the formation of beads in an effort to minimize the surface area [118]. However,
increase in concentration results in increased viscoelastic forces which overcome the
surface tension of the solution. Hence, 20% wt/vol concentration resulted in formation of
bead-free uniform fiber morphology. The presence of smooth cylindrical fibers is likely
in the event of solvent evaporating completely before reaching the collector plate.
Because of production of good quality fibers using 20 wt%/vol solution, the fibers spun
with 20 wt%/vol solution were considered for all experiments mentioned in this study.
![Page 66: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/66.jpg)
52
Fig. 22. Represents Silica nanofibers (a, b) produced at 20 wt% precursor solution. Uniform diameter fibers were observed. No bead or droplet formation was observed.
Distribution of silica nanofiber diameter is critical to the mechanical and physical
properties of the composite resin materials. Fiber specifically within a range of 150 – 500
nm are used for reinforcing in dental composites, since fibers with diameters larger than
500 nm would most likely to behave like that of a micrometer-sized fiber which results in
decrease volumetric fraction and increase inter-particle spacing. On the other side, fibers
with dimensions less than 150 nm in diameter will have questionable effectiveness in
their ability to blunt crack growth. Therefore, fibers in ranges of diameter between the
150 – 500 nm may possess an acceptable surface area-to-volume ratio, which may also
play a role in enhancing the bonding between fibers and matrix, and act as matrix
toughness. Diametrical changes in SNF after calcification were observed using SEM
images (figure 23 (a, b)).
a) 500 X b) 5000 X
![Page 67: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/67.jpg)
53
Fig. 23. (a,b) represents SNF after calcinations at 4000x and 14,000x.
Diameter of SNF before and after calcination was measured on SEM micrographs
with Image Analyzer software (Image-J, Image Processing and Analysis in JAVA).
Hundred counts were made per micrograph to measure and compare SNF diameter within
on SEM micrograph. Figure 24 represents diametrical distribution of SNF before
calcination (PVP-SNF) and after calcinations (SNF). For uncalcinated fibers (SNF-PVP),
maximum percentages of fibers were observed in a range of 400-500 nm, however, for
calcinated fibers (SNF-C), maximum percentages of fibers were observed in the range of
300-400 nm. On an average, the calcined Silica nanofiber (SNF-C) were about 1.4 times
smaller in comparison with uncalcinated fibers (PVP-SNF), which was consistent with
other studies involving the removal of a binder [92].
a)4000X b)14,000X
![Page 68: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/68.jpg)
54
Fig. 24. Represents silica nanofibers diameter distribution before (PVP-SNF) and after calcinations (SNF-C).
Efficiency of silica nanofiber production using electrospinning technique was
determined in terms of the solution yields, the masses of pre- and post-calcinated samples
were calculated per 4 ml of solution using equation 5.
−
p
sp
MMM
*100
Where,
MP = Mass of precursor solution
MS = Mass of calcinated solution
Efficiency of silica nanofiber production using electrospinning technique
determined in terms of solution yield was approximately 7%. Although the reduction in
[Equation 5]
![Page 69: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/69.jpg)
55
fiber diameter was not consistent with the mass loss after calcination, the above method
of calculating mass loss is an effective way to determine the yield of the solution for
scaling the process to generate larger quantities.
7.1.2 Fourier Transform Infrared Spectroscopy (FTIR)
Fourier Transform Infrared spectroscopy (FTIR) spectrum of SNF (uncalcinated
and calcinated) was performed to confirm that calcination had occurred (Figure 25). This
was done by identifying the Si–O peak at 795, 950 and 1058 cm-1 [119]. A broad band
near 3390 cm-1 is assigned to O-H vibration. The peaks due to PVP at 1650 cm-1 (C=O),
several strong peaks methyl (-CH3) 2800-3000 cm-1 and methylene (-CH2) 1400-1800
cm-1 of ethyoxy group were present before calcination but disappear in the post-calcined
sample, as expected [120].
Fig. 25. Represents FT-IR spectrum comparing calcinated and un-calcinated silica nanofibers.
![Page 70: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/70.jpg)
56
7.1.3 X-Ray diffraction (XRD)
X-Ray diffraction was used to confirm the crystallographic structure of SNF and is
represented in figure 26. The XRD profile of SNF showed wide peak at 2ϴ angle of 21º.
This XRD pattern is the characteristic of amorphous silica [121].
Fig. 26. XRD of SNF with peak at 2ϴ angle of 21º shows amorphous silica.
![Page 71: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/71.jpg)
57
7.2 Testing of Mechanical and Physical Properties
7.2.1 Rheology (visco-elastic property)
The frequency sweep as seen in Figure 27 showed a nominal difference in
viscosity with increasing shear rate and increase in filler load percentage. As discussed in
section 5.4.1, rheology is an assessment of handling properties of restorative material and
their ability to adapt cavity walls during restoration of cavity. Within the limitation of this
study, figure 27 suggests that incorporation up to 20wt% nanofibers and 20wt% mixture
of silica nanofiber and silica nanoparticle into the dental resin had minimal effect on its
handling characteristics. The clear/unfilled resin and experimental groups (20wt% and
20wt%H) didn’t show significant shear thinning behavior, compared with the experimental
group with high SNF filler load (35.8wt%). 35.8wt% experimental groups showed highest
viscosity among all groups initially, however under constant shear rate, showed same
viscosity like unfilled and groups with low filler load. This effect of experimental group
35.8wt% SNF could be because the nanofibers under constant shear tend to align along the
direction of flow, thereby offering lower resistance to motion.
The highly filled composite on the other hand, displayed a Newtonian behavior with
an approximately three-fold higher viscosity than the other groups. Decreased in viscosity
was observed followed by gradual increase. This effect could be because of morphology of
silica filler particles. Initial decrease in viscosity could be because of movement of silica
filler particles away from each other under strain. However, further movement of silica filler
particles were inhibited due to intermolecular attraction between filler particles which
resulted in increase in viscosity with time.
![Page 72: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/72.jpg)
58
Fig. 27 Represents change in viscosity of different experimental groups (20wt%, 35.8wt% and 20wt% H) compared with unfilled and highly filled (PermaFlo) composite resins.
7.2.2 Gloss
Gloss is an aspect of the visual perception of objects that is as important as color
when considering the psychological impact of products on a consumer. It has been
defined as 'The attribute of surfaces that causes them to have shiny or lustrous, metallic
appearance”. 20wt% showed highest gloss units on the scale of 0-100, among all
experimental groups, however, Tukey’s test shows no significant difference between
20wt%, 35.8wt% and PermaFlo. Unfilled resin showed lowest gloss value and 20wt% H
showed higher gloss values than unfilled and lower gloss values compared to other
experimental groups (figure 28).
![Page 73: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/73.jpg)
59
Fig 28 Represents comparison of mean and SD gloss values of all tested groups.
7.2.3 Degree of conversion
The FT-IR spectra for uncured and cured (24 hour post cure) samples were obtained
for the five resin based groups. The percentage DC and measurement of DC using FT-IR
spectra for the composite groups are depicted in Figure 29 and Figure 30 respectively.
Fig. 29 Represents comparison of degree of conversion among tested groups (Mean±SD)
![Page 74: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/74.jpg)
60
Degree of conversion and final properties of cured composite resins depends on
polymeric matrix, percent filler particles and filler loads and percentage of photoinitiators in
a composite resin system [122, 123]. The bis-GMA containing matrix possesses two aromatic
rings per molecule as well as high intermolecular hydrogen bonding. This significantly
reduces the mobility of the monomer chains making it highly viscous and compromising the
degree of conversion. This effect can be reduced by the addition of lower molecular weight
resins like TEGMA. The addition of the lower molecular weight TEGDMA improves the
movement of the chains and in addition, the aliphatic nature of the molecule allows for a
higher degree of conversion.
Fig. 30. Degree of conversion was measured by comparing absorption peaks of aliphatic C=C (1638 cm-1) and aromatic C-C peaks (1608 cm-1) using equation 5.
Since all the tested groups have same resin formulation, the degree of conversion
obtained for all the groups is a function of the filler particles. The incorporation of various
percentages of filler loads into resin system reduces the overall monomer content; and, hence,
results in fewer aliphatic conversions of bis-GMA monomer. This is validated from the
![Page 75: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/75.jpg)
61
degree of conversion seen for highly filled SNF (35.8wt%) and highly filled SFP [PermaFlo
(68wt%)] composite. These results are in conjunction with similar studies involving highly
filled dental composite resins [122]. No significant difference was observed between unfilled,
20wt% and 20wt% H and showed high degree of conversion in range of 62-65%. The DC
values obtained for both the highly filled groups [35.8wt% and PermaFlo (68wt%)] showed
lower DC than other above motioned groups. This can also be attributed to the light
scattering phenomenon referred to in Section 6.2.2. Arikawa et al have shown that when light
in the visible blue range is used to cure samples containing filler particles predominantly
below 500 nm, there is a scattering of the light beam [124]. This scattered light results in
compromised activation of photoinitiators like camphoroquinone present in the matrix, which
acts as an initiator for the monomer conversion. Lower degree of conversion has also affected
the performance of these samples in the analysis of wear. In order to achieve an improvement
in wear mechanics of these experimental composites, the more percentage of photoinitiors
must be incorporated to further increase in degree of conversion or material should be cured
for longer time.
7.2.4. Polymerization Shrinkage
The results of the polymerization shrinkage tests using ACUVOL, volumetric shrinkage
analyzer, confirmed that the addition of various percentages of experimental fillers loads
(nanofibers and silica particles) reduced the polymerization shrinkage of the composite as
represented graphically in Figure 31. The reason for this change in the polymerization
dynamics of the resin is two pronged. First, the incorporation of the different nanofillers into
composite resin reduces the fraction of shrinkable monomers to begin with, leading to
decreased polymerization shrinkage [24]. Second, the addition of fillers greatly reduces the
mobility of the monomer chains and, hence, the ability of the free radical species to react
![Page 76: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/76.jpg)
62
effectively with the resin [123].
Fig. 31. Represents comparison of polymerization shrinkage percentages and standard deviation values of all experimental groups (Mean±SD).
The Tukey test showed a significant decrease in the percentage shrinkage values
between the clear unfilled group and other tested groups. No significant difference was
observed between 20wt% and 20wt% H and between 35.8wt% and Permaflo (68wt%). This
data is in concurrence with the DC data, with the two tested groups (35.5wt% and PermaFlo)
showing the least density of cross-linking and hence the least amount of polymerization
shrinkage.
7.2.5. Three Body Wear
ProForm software was used to calculate volumetric loss of wear specimens. The original
surfaces of the specimens were scanned using PROSCAN before they were subjected to three
body wear in the Alabama Wear Testing machine. Wear facets on specimens were observed
after completion of 200,000 load cycles, the specimens were re-scanned targeting the wear
facets. The original and the modified (post-wear) scans were then superimposed in ProForm
to create the individual volumetric wear pattern for each set of scans, as seen in Figure 32.
![Page 77: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/77.jpg)
63
Fig. 32. (a,b,e,f) represents superimposed scans generated using PROFORM software in which, top surface represents pre-wear surface and bottom image represents post-wear image of all groups 20wt%, 35.8wt%, 20wt% H and Permaflo respectively. (c,d,g,f) represents wear pattern observed in all groups in same order as mentioned above.
a) b)
c) d)
e) f)
g) h)
![Page 78: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/78.jpg)
64
Fig. 33. Comparison of volumetric loss (mm3) among all experimental groups (Mean±SD).
The Alabama wear simulator translates 100,000 cycles to 1 yr of in vivo wear. The
simulator uses a force of 75 N, and an impact and twisting movements. This movement helps
to create a localized wear pattern which simulate wear pattern experienced in the mouth.
Figure 33 provides a graphical representation of the wear volumes and standard deviations
for each group. 20wt% H showed lowest volumetric loss, however, no significant difference
was observed between 20wt% H and 20wt% using Tukey’s test. 35.8wt% showed highest
volumetric loss whereas, PermaFlo (68wt%) showed less volumetric loss compared to
35.8wt% and higher volumetric loss as compared to 20wt% and 20wt% H.
The results show that the 5.2% SNF and the 5.2% SNP have experienced more wear
compared to the traditional flowable resin group. However, the Mann-Whitney test illustrated
that the variation in the volume of wear was not statistically significant for any of the four
groups. It has been seen that high volume of wear can be seen in resin systems with less filler
load. This is attributed to high interparticle spacing, which results in high percentage of
intervening soft resin matrix in between filler particles and is worn at a much faster rate
![Page 79: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/79.jpg)
65
leading to a high early wear [116]. However, within the limitation of this study, group with
high percentages of SNF (35.8wt%) and highly filled composite resin PermaFlo (68wt%)
showed higher volume loss. This has been attributed to a light scattering effect occurring at a
wavelength of 470 nm for nanoscaled fillers. Thus, the light intensity might have been
attenuated and the degree of cure compromised, leaving behind a large amount of unreacted
methacrylate groups which are mechanically weak and tend to wear easily. The FT-IR
analysis of the degree of cure for these bis-GMA based composite samples can provide an
insight into the wear performance of these materials.
7.2.6. Fracture Toughness and flexural strength
Fracture toughness is a property which describes the ability of a material
containing crack to resist fracture and is determined based on their KIC values. The
energy for the growth of the crack comes either from external work done or from a stored
strain. The KIC values for all experimental groups, used in this study are shown in Figure
34.
Fig. 34. Comparison of KIc values (with Standard deviations) for all 5 tested groups (Mean ± SD)
![Page 80: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/80.jpg)
66
As expected, the addition of silanated fibers in the resin matrix improved the
fracture toughness of experimental groups. One way ANOVA and Tukey tests were used
to determine intergroup group differences among the fracture specimens. Addition of
20wt% of SNF significantly increased fracture toughness. No significant difference was
observed between 20 wt%, 35.8 wt% and 20 wt% H. This signifies that presence of SNF
and SNF and SFP significantly stopped crack propagation. Previous studies [125] showed
that increase in filler load of SNF within resin matrix results in decrease in fracture
toughness due to agglomeration of fibers, however no significant decrease in fracture
toughness was seen after adding SNF filler load from 20 wt% to 35.8 wt%. In order to
develop a better understanding of the toughening mechanism of all the different filler
types, an SEM analysis of the fractured surfaces was conducted.
The fractured specimens were examined under SEM to develop an insight into the
fracture mechanics of the different compositions of the dental composite resin. The clear
resin specimens showed a glassy fracture pattern as depicted in Figure 35 (a). A smooth
region can be identified in Figure 35 (b), where the crack had propagated rapidly, which
is also characterized by coarse and flat regions at the protruding ridges of the fractured
surface. This type of brittle fracture is characterized by a sudden fracture with barely any
plastic deformation [121]. Such fracture patterns are indicative of very little resistance
being offered to the advancing fracture line.
The highly filled composite resin [Permaflo (68wt%)] specimens [Figure 35 (c)]
shows the appearance of cleavage faces similar to those seen in other more brittle
materials like ceramics. The Permaflo contains a high percentage (68%) of silica filler
particles. The micron-sized particles present in the specimens presumably redirected the
fracture lines, thereby increasing the work done for fracture for this material.
![Page 81: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/81.jpg)
67
Fig. 35 SEM images of fractured surfaces: (a, b) clear resin specimens with distinct ridges formed due to a brittle fracture, (c) PermaFlo specimen with areas of irregular cleavages.
The SNF reinforced composites 20wt%, 35.5 wt% and 20 wt% H, showed an
improvement in fracture toughness over the clear resin. Figure 36 (a, b,c) showed a
conchoidal fracture pattern with tear lines leading away from the origin of the crack. At
some place, there were visible areas of polymer sheaths separating, representative of a
material with low toughness. Small troughs in all figure 36 (a,b,c) were expected to be
left over space after fiber pull-out under load application. This showed strong bonding
between fibers and resin matrix, however at some places projected SNF can be seen from
a) b)
c)
![Page 82: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/82.jpg)
68
the resin matrix. It shows that improvement is needed in silanition of SNF. Figure 36 (c)
shows non uniform distribution of SFP within the experimental groups and large
agglomerates of SFP can be observed.
Fig 36 shows distribution of various filler loads and fracture pattern in 20 wt% (a), 35.8 wt% (b) and 20 wt% H (c). Arrows in a) indicates fiber pull out and SNF projected from resin matrix and crack propagation. Arrows in b) represents fracture pattern and projected SNF from resin matrix. Arrows in c) represent fiber pull-out, non uniform distribution of SFP.
The SNF reinforced samples (20wt%, 35.8wt%) showed a complex fracture pattern
suggestive of a toughened matrix. As observed in Figures 30 (a, b and c) for the SNF
specimens, fracture surfaces in fiber containing composites may have fibers protruding
out of the matrix. This phenomenon toughens the composite, especially in case of
a) b)
c)
![Page 83: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/83.jpg)
69
composites containing discontinuous fibers. A critical transfer length between fibers and
matrix is necessary for effective transfer of loads. If the distance between the matrix
crack and the end of discontinues fiber is less than the critical length, a fiber pull out, as
seen in Figure 36 (a), occurs instead of the fiber fracturing within the matrix [116].
According to the Cottrell and Kelly model (1964), the work done against friction is stored
as a pull out energy, and, subsequently creates a significant resistance to crack growth.
The pulled out fibers also resulted in bridging the cracks. Hence, the fiber reinforced
composites show need for an increased work to fracture. Therefore, dental composites
reinforced with fibers show need for an increased work to fracture. When the distance
between nanofiber end and propagating crack front is larger than the critical transfer
length, fiber fracture occurs. The stress created in the interfacial region results in de-
bonding of the matrix around the fiber; this frictional stress opposes the pull out of the
fibers from the matrix. De-bonding of the matrix from the fibers further toughens
composites since work is done in the creation of the new surfaces. However, figure 37
(a,b,c) shows smooth surfaces of trough followed by fiber pull out, which is suggestive
of weak bonding between resin matrix and SNF.
In 1964, Cook-Gordon studied crack-propagation, and proposed mechanism of
crack propagation. Crack always grow in a direction requiring least applied load or
weakest material strength. Tensile stresses, approximately 20% the magnitude of stresses
at the tip of the crack, run parallel to direction of crack propagation. Whenever a weak
interface presents itself in the path of the advancing crack, de-bonding occurs ahead of
the crack and a “T-shaped” blunting can be observed, thereby toughening the system. In
1974, Atkins and Marston proposed that if the fibers were oriented to create random areas
of high and low shear stresses, the Cook-Gordon model would be justified.
![Page 84: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/84.jpg)
70
Since, the silica fillers were surface treated with silane coupling agent before
being incorporated into the matrix, the presence of a strong interfacial bonding along with
improving the overall strength of the material may be expected to contribute to
toughening the material. However, fracture models developed with reference to
interfacial parameters have shown a strong bond to be detrimental to the fracture
properties of the material [126]. A weaker interfacial bond on the other hand, is preferred
in preventing crack propagation since fiber pull out and higher stresses are created in the
interfacial matrix. Since the SNF reinforced specimens performed well under fracture,
this suggests the presence of areas of both strong and weak bonding existing within the
SNF reinforced matrix [127]. The randomly dispersed fibers with no distinct orientation
may presumably have contributed to this discrepancy in interfacial bonding.
![Page 85: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/85.jpg)
71
8. NULL HYPOTHESIS REJECTION
No difference will be observed in the mechanical and physical properties of
flowable composites produced by adding different filler load, compared with unfilled
composite resin and highly filled flowable composite resin was rejected.
![Page 86: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/86.jpg)
72
9. CONCLUSION
The objective of this study was to fabricate silica nanofibers and blend them with
commercially available resin monomer to form highly reinforced direct filling flowable
composite resin with improved mechanical and physical properties. The SNF were
fabricated using electrospinning technique, which was optimized to obtain bead free
morphology cylindrical fibers with average diameters in the range of 300 - 450 nm. The
electrospun SNF heat treated in order to remove the binder polymer. Characterization of
morphology of prepared fibers was done using scanning electron microscopy (SEM), for any
surface defects, FT-IR was used to determine composition of the fibers and crystallography
of SNF was determined using XRD. The silica fibers were then surface treated at
ULTRADENT, Inc., Utah, with silane coupling agent in order to improve the bonding
between the fibers and the bis-GMA/TEGDMA resin mixture into which they were to be
incorporated. Experimental groups with various wt% of filler loads were prepared (20wt%,
35.8wt% and 20wt% H). Unfilled and highly filled [PermaFlo (68wt%)] were tested as
negative and positive control respectively. The samples containing the SNF were translucent
to light, and were glossy after polishing. Since esthetics is an important criterion for
composite restorations, these materials hold promise in the cosmetic restoration segment. The
improvement in all mechanical properties were observed after incorporation of SNF and
SNF:SFP mixture. Among all the experimental groups 20wt% H showed highest fracture
toughness, flexural strength and wear resistant. Incorporation of SNF also improved
![Page 87: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/87.jpg)
73
rheological properties of flowable composite. 35.8wt% experimental group showed best
handling properties under shear rate and 20wt% showed highest gloss values. 20wt% H
showed highest degree of conversion whereas 35.8wt% showed lowest degree of conversion.
All experimental groups showed high polymerization shrinkage as compared to PermaFlo.
The SNF have also shown the ability to be silanated and dispersed evenly into the
resin matrix, thereby negating the ill effects of filler agglomeration associated with nano-
dimension particles. By increasing the filler loading and filler distribution, better control of
the inter-particulate spacing in the prepared composites can be achieved and the wear
resistance of these materials may be improved. However, due to the limitations of this study,
further work could not be accomplished.
Future research in this area should be directed towards the development of
multiscaled composites containing various percentages of hybrid fillers, micronsized
particulate fillers along with the silica nanofibers, optimizing the length of SNF and
improvement of coupling agent application is required. Understanding the effect of the
interaction of all these fillers on the properties of dental composite provides a stimulating
research opportunity. The new generation of dental composites with the combination of
fillers proposed, will have enhanced clinical performance.
![Page 88: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/88.jpg)
74
LIST OF REFERENCES
1. Sheldon, T. and E. Treasure, Dental restoration: what type of filling? Effective health care bulletins, 1999. 5(2): p. 1-12.
2. USA.gov, Healthy People 2010: Objectives for Improving Health (Part B: Focus Areas 15-28), in Healthy People.gov website. 2000.
3. Beazoglou, T., et al., Economic Impact of Regulating Amalgam Restorations Public Health Reports, 2007. 122.
4. Wilwerding, T., History of Dentistry. 2006. p 3-15. 5. Letzel, H., et al., A controlled clinical study of amalgam restorations: survival,
failures, and causes of failure. Dental Materials, 1989. 5(2): p. 115-121. 6. Jordan, R.E. and M. Suzuki, Posterior composite restorations. Where and how
they work best. J Am Dent Assoc, 1991. 122(11): p. 30-37. 7. Christensen, G.J., Amalgam Vs. Composite Resin: 1998. J Am Dent Assoc, 1998.
129(12): p. 1757-1759. 8. Ernst, C.-P., et al., Clinical performance of a packable resin composite for
posterior teeth after 3 years. Clinical Oral Investigations, 2001. 5(3): p. 148-155. 9. D.W, J., Dental Composite Biomaterial. Journal of Canadian Dental Association,
1998. 64(10): p. 3. 10. Council On Scientific Affairs, A.D.A., Direct and indirect restorative materials.
Journal of American Dental Association, 2003. 134(4): p. 463-472. 11. Collins, C.J., R.W. Bryant, and K.L.V. Hodge, A clinical evaluation of posterior
composite resin restorations: 8-year findings. Journal of Dentistry, 1998. 26(4): p. 311-317.
12. Daou, M.H., Clinical evaluation of four different dental restorative materials: one-year results. Schweizer Monatsschrift für Zahnmedizin, 2008. 118: p. 290.
13. Dilley, D.H., et al., Time required for placement of alloy versus resin posterior restorations. J Dent Res, 1985. 64(spec issue): p. 350 abst #1583.
14. Combe, E.C. and F.J.T. Burke, Contemporary resin-based composite materials for direct placement restorations: packables, flowables and others. Dent Up, 2000. 27: p. 326-336.
15. Albers, H.F., Tooth-colored restoratives. 8th ed. 1996, Santa Rosa. 5b-2. 16. Hosoya, Y., Five-year color changes of light-cured resin composites: influence of
light-curing times. Dent Mat, 1999. 15: p. 353-362. 17. Dietschi, D., et al., Comparison of the color stability of ten new-generation
composites: An in vitro study. Dent Mat, 1994. 10: p. 353-362. 18. Stansbury, J.W., Curing dental resins and composites by photopolymerization. J
Esthet Dent, 2000. 12: p. 300-308. 19. Albers, H.F., Resin polymerization. ADEPT Report, 2000. 6(3).
![Page 89: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/89.jpg)
75
20. Ferracane, J. and E. Greener, The effect of resin formulation on the degree of conversion and the mechanical properties of dental restorative resins. J Biomed Mater Res, 1986. 20: p. 121-131.
21. Davidson, C., A. De Gee, and A. Feilzer, The competition between the composite-dentin bond strength and the polymerization contraction stress. J Dent Res, 1984. 63(12): p. 1396-9.
22. Suliman, A., D.B. Boyer, and R.S. Lakes, Polymerization shrinkage of composite resins: comparison with tooth deformation. J Prosthet Dent, 1994. 71(7-12).
23. Feilzer, A., A. de Gee, and C. Davidson, Setting stress in composite in relation to configuration of the restoration. J Dent Res, 1987. 66(11): p. 1636-1639.
24. Alster, D., et al., Influence of compliance of the substrate materials on polymerization contraction stress in thin resin composite layers. Biomaterials, 1997. 18: p. 337-341.
25. Braga, R. and J. Ferracane, Contraction stress related to degree of conversion and reaction kinetics. J Dent Res, 2002. 81(2): p. 114-118.
26. Xu HH, Quinn JB, Smith DT, Giuseppetti AA, Eichmiller FC. Effects of different whiskers on the reinforcement of dental resin composites. Dent Mater. 2003 Jul;19(5):359-67.
27. Musanje L, Ferracane JL., Effects of resin formulation and nanofiller surface treatment on the properties of experimental hybrid resin composite. Biomaterials. 2004 Aug;25(18):4065-71.
28. Rodrigues Junior SA, Zanchi CH, Carvalho RV, Demarco FF. Flexural strength and modulus of elasticity of different types of resin-based composites. Braz Oral Res. 2007 Jan-Mar;21(1):16-21.
29. Leinfelder KF, Sluder TB, Santos JFF, Wall JT. Five-year clinical evaluation of anterior and posterior restorations of composite resins. Oper Dent. 1980;5:57-65.
30. Manhart J, Chen HY, Hamm G, Hickel R. Buonocore Memorial Lecture. Review of the clinical survival of direct and indirect restorations in posterior teeth of the permanent dentition. Oper Dent. 2004;29(5):481-508.
31. Bayne, S. and D. Taylor, Dental Materials, in The Art and Science of Operative Dentistry, C. Sturdevant, Editor. 1995, Mosby: St. Louis.
32. Craig R.G. (Ed.), Restorative dental materials 10, Mosby Publishing Co, St. Louis, MO, 1997.
33. Spanoudakis Y, Young R.J. Crack propagation in a glass particle-filled epoxy resin. Part I. Effect of particle volume fraction and size, J. Mater. Sci. 19 (1984) 473–486.
34. Spanoudakis Y, Young R.J. Crack propagation in a glass particle-filled epoxy resin. Part II. Effect of particle–matrix adhesion, J. Mater. Sci. 19 (1984) 487–496.
35. Braem M, Lambrechts P, Van Doren V, Vanherle G. The impact of composite structure on its elastic response. J Dent Res. 1986;65(5):648-53.
36. Ikejima I, Nomoto R, McCabe JF. Shear punch strength and flexural strength of model composites with varying filler volume fraction, particle size and silanation. Dent Mater. 2003 May;19(3):206-11.
37. Kim KH, Ong JL, Okuno O. The effect of filler loading and morphology on the mechanical properties of contemporary composites. J Prosthet Dent. 2002;87(6):642-9.
![Page 90: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/90.jpg)
76
38. Vallittu PK Comparison of two different silane compounds used for improving adhesion between fibers and acrylic denture base material. J Oral Rehabil 1993;20:533-9.
39. Moszner N, Salz U. New developments of polymeric dental composites. Progr Polym Sci 2001;26:535–76.
40. Mitra SB, WU D, Holmes BN. An application of nanotechnology in advanced dental materials. J Am Dent Assoc 2003;134:1382–90.
41. Venhoven BA, de Gee AJ, Werner A, Davidson CL. Influence of filler parameters on the mechanical coherence of dental restorative resin composites, Biomaterials 17 (1996) 735–740.
42. Leinfelder KF Posterior composites. State-of-the-art clinical applications, Dent. Clin. North Am. 37 (1993) 411–418.
43. Manhart J, Kunzelmann KH, Chen HY, Hickel R. Mechanical properties and wear behavior of light-cured packable composite resins. Dent Mater. 2000 Jan;16(1):33-40.
44. Narva. KK, Vallittu PK, Helenius H, Yli-Urpo A. Clinical survey of acrylic resin removable denture repairs with glass-fiber reinforcement. Int J Prosthodont. 2001 May-Jun;14(3):219-24.
45. Goldberg AJ, Burstone CJ. The use of continuous fiber reinforcement in dentistry. Dent Mater 1992;8:197-202.
46. Ruyter IE, Ekstrand K, Bjork N. Development of carbon/graphite fiber reinforced poly (methyl methacrylate) suitable for implant-fixed dental bridges. Dent Mater 1986;2:6-9.
47. Vallittu PK. Some aspects of the tensile strength of unidirectional glass fibre-polymethyl methacrylate composite used in dentures. J Oral Rehabil 1998;25:100-5.
48. Vallittu PK. Flexural properties of acrylic resin polymers reinforced with unidirectional and woven glass fibers. J Prosthet Dent 1999;81:318-26.
49. Xu HH, Schumacher GE, Eichmiller FC, Peterson RC, Antonucci JM, Mueller HJ. Continuous-fiber preform reinforcement of dental resin composite restorations. Dent Mater. 2003 Sep;19(6):523-30.)
50. Griffith AA. The phenomena of rupture and flow in solids. London: Philos. Trans Roy Soc; 1920. p. 221.
51. Pisol Senawongse, P.P., Surface Roughness of Nanofill and Nanohybrid Resin Composites after Polishing and Brushing. Journal of Esthetic and Restorative Dentistry, 2007. 19(5): p. 265-273.
52. Marquis, P., et al., Variability of the deformation behaviour of nanoclusters of nanoparticles, in IADR/AADR/CADR 85th General Session and Exhibition 2007: New Orleans, LA.
53. Chronakis, I.S., Novel nanocomposites and nanoceramics based on polymer nanofibers using electrospinning process--A review. Journal of Materials Processing Technology, 2005. 167(2-3): p. 283-293.
54. Bergshoef, M.M. and G.J. Vancso, Transparent Nanocomposites with Ultrathin, Electrospun Nylon-4, 6 Fiber Reinforcement. Advanced Materials, 1999. 11(16): p. 1362-1365.
55. Dodiuk-Kenig, H., et al., The effect of grafted caged silica (polyhedral oligomeric silesquioxanes) on the properties of dental composites and adhesives.
![Page 91: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/91.jpg)
77
Journal of Adhesion Science and Technology, 2006. 20: p. 1401-1412. 56. Dodiuk-Kenig, H., et al., Performance Enhancement of Dental Composites Using
Electrospun Nanofibers. Journal of Nanomaterials, 2008. 2008: p. 6 pages. 57. Choi, S.-S., et al., Silica nanofibers from electrospinning/sol-gel process. Journal
of Materials Science Letters, 2003. 22(12): p. 891-893. 58. Hsiao, B.S., C. Burger, and B. Chu, Nanofibrous Materials and their
Applications. Annual Review of Materials Research, 2006. 36: p. 333. 59. Roberson, T., H. Heymann, and E. Swift, Sturdevant's Art and Science of
Operative Dentistry. 2006: Mosby. p 1040. 60. Bowen, R.L., Journal of American Dental Association, 1963. 66: p. 57. 61. H. Ishida, J.L.K., The reinforcement mechanism of fiber-glass reinforced plastics
under wet conditions: A review. Polymer Engineering & Science, 1978. 18(2): p. 128-145.
62. Karmaker, A., A. Prasad, and N. Sarkar, Characterization of adsorbed silane on fillers used in dental composite restoratives and its effect on composite properties. Journal of Materials Science: Materials in Medicine, 2007. 18(6): p. 1157-1162.
63. Debnath S. et al. Interface effects on on mechanical properties of particle-reinforced composites. Dental Materials, 2004. 20(7): p. 677-686.
64. Ash, B.J., R.W. Siegel, and L.S. Schadler, Glass-transition temperature behavior of alumina/PMMA nanocomposites. Journal of Polymer Science Part B: Polymer Physics, 2004. 42(23): p. 4371-4383.
65. Moore, R.J., et al., Intra-oral temperature variation over 24 hours. European Journal of Orthodontics, 1999. 21(3): p. 249-61.
66. Hoelscher, D., et al., The effect of three finishing systems on four esthetic restorative materials. Operative Dentistry, 1998. 23: p. 36–42.
67. Leinfelder, K.F., et al., Clinical evaluation of composite resins as anterior and posterior restorative materials. Journal of Prosthetic Dentistry, 1975. 33: p. 407–416.
68. Reusens, B., W. D‟ hoore, and J. Vreven, In vivo comparison of a microfilled and a hybrid minifilled composite resin in class III restorations: 2-year follow-up. Clinical Oral Investigations, 1999. 3(2): p. 62-69.
69. Anusavice, K.J., Phillips' Science of Dental Materials. eleventh ed. Vol. Eleventh Edition: WB Saunders
70. Kim, K.-H., J.L. Ong, and O. Okuno, The effect of filler loading and morphology on the mechanical properties of contemporary composites. The Journal of Prosthetic Dentistry, 2002. 87(6): p. 642-649.
71. Tian M, et al., Bis-GMA/TEGDMA Dental Composites Reinforced with Electrospun Nylon 6 Nanocomposite Nanofibers Containing Highly Aligned Fibrillar Silicate Single Crystals. Polymer (Guildf), 2007. 48(9): p. 2720-2728.
72. Xu, H.H., et al., Effects of different whiskers on the reinforcement of dental resin composites. Dental Materials, 2003 5(19): p. 359-367.
73. Xu, H.H.K., et al., Continuous-fiber preform reinforcement of dental resin composite restorations. Dental Materials, 2003. 19(6): p. 523-530.
74. Matinlinna, J., et al., Effect of the cross-linking silane concentration in a novel silane system on bonding resin-composite cement. Acta Odontologica Scandinavica, 2008. 66(4): p. 250-255.
75. Schneider, L.F.J., et al., Influence of photoinitiator type on the rate of
![Page 92: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/92.jpg)
78
polymerization, degree of conversion, hardness and yellowing of dental resin composites. Dent Mater, 2008. 24(9): p. 1169-1177.
76. Kumbar, S.G., et al., Electrospun nanofiber scaffolds: engineering soft tissues. Biomedical Materials, 2008. 3(3): p. 034002.
77. Nain, A.S., et al., Drawing Suspended Polymer Micro/Nanofibers Using Glass Micropipettes. Applied Physics Letters, 2006. 89(18).
78. Harfenist, S.A., et al., Direct Drawing of Suspended Filamentary Micro- and Nanostructures from Liquid Polymers. NANO LETTERS, 2004. 4(10).
79. Whitesides, G.M. and B. Grzybowski, Self-Assembly at All Scales. Science, 2002. 295(5564): p. 2418-2421.
80. Schonenberger, C., et al., Template Synthesis of Nanowires in Porous Polycarbonate Membranes: Electrochemistry and Morphology. The Journal of Physical Chemistry B, 1997. 101(28): p. 5497-5505.
81. Martin, C.R., Nanomaterials: A membrane-based synthetic approach. Science, 1994. 266(5193): p. 6.
82. Lee, S.B.,http://mrsec.umd.edu/Research/Seeds.html#Template in Materials Research Science and Engineering Center, University of Maryland. accessed 26th March 2009.
83. Li, D. and Y. Xia, Electrospinning of Nanofibers: Reinventing the Wheel? Advanced Materials, 2004. 16(14): p. 1151-1170.
84. Greiner, A. and J.H. Wendorff, Electrospinning: A Fascinating Method for the Preparation of Ultrathin Fibers. Angewandte Chemie International Edition, 2007. 46(30): p. 5670-5703.
85. Doshi, J. and D.H. Reneker, Electrospinning process and applications of electrospun fibers. Journal of Electrostatics, 1995. 35(2-3): p. 151-160.
86. Hunt, J.A., K.D. Andrews, and A.B. Richard, Technology of electrostatic spinning for the production of polyurethane tissue engineering scaffolds. Polymer International, 2007.
87. Kameoka J., et al. A scanning tip electro spinning source for deposition of oriented nanofibers. Nanotechnology, 2003. 14: p. 1124.
88. Kim, G.H., et al., An applicable electrospinning process for fabricating a mechanically improved nanofiber mat. Polymer Engineering & Science, 2007. 47(5): p. 707-712.
89. Ren, J., et al., Mechanical Properties of a Single Electrospun Fiber and Its Structures. Macromolecular Rapid Communications, 2005. 26: p. 716.
90. Venugopal, J., et al., Biocomposite nanofibres and osteoblasts for bone tissue engineering. Nanotechnology, 2007. 18(5).
91. McCann, J.T., D. Li, and Y.N. Xia, Electrospinning of nanofibers with core-sheath, hollow, or porous structures. Journal of Materials Chemistry, 2005. 15(7): p. 735-738.
92. H.-W., K., K.H. E., and K.J. C, Production and Potential of Bioactive Glass Nanofibers as a Next-Generation Biomaterial. Advanced Functional Materials, 2006. 16(12): p. 1529-1535.
93. Jipin, Z. and C.G. David, Processing and properties of sol– gel bioactive glasses. Journal of Biomedical Materials Research, 2000. 53(6): p. 694-701.
94. Reneker, D.H., et al., Nanofiber manufacturing: Toward better process control. Polymeric Nanofibers, 2006. 918: p. 7-+.
![Page 93: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/93.jpg)
79
95. Fu, G.D., et al., Smart Nanofibers from Combined Living Radical Polymerization," Click Chemistry ", and Electrospinning. ACS Applied Materials & Interfaces, 2009. 1(2): p. 239-243.
96. Chuachamsai, A., S. Lertviriyasawat, and P. Danwanichakul, Spinnability and Defect Formation of Chitosan/Poly Vinyl Alcohol Electrospun Nanofibers. Thammasat International Journal of Science and Technology, 2008. 13: p. 24-29.
97. Fong, H., I. Chun, and D.H. Reneker, Beaded nanofibers formed during electrospinning. Polymer, 1999. 40(16): p. 4585-4592.
98. Yu, J.H., S.V. Fridrikh, and G.C. Rutledge, The role of elasticity in the formation of electrospun fibers. Polymer, 2006. 47(13): p. 4789-4797.
99. Brinker, J.C. and G.W. Scherer, Sol-gel science: the physics and chemistry of sol-gel processing. 1990: Boston: Academic Press.
100. Heintze, S.D., How to qualify and validate wear simulation devices and methods. Dental Materials, 2006. 22(8): p. 712-734.
101. Choi, S.-S., et al., Silica nanofibers from electrospinning/sol-gel process Journal of Materials Science Letters, 2003. 22(12): p. 891-893.
102. Kanehata, M., B. Ding, and S. Shiratori, Nanoporous ultra-high specific surface inorganic fibres. Nanotechnology, 2007. 18(31).
103. www.micro.magnet.fsu.edu/primer/java/interference/index.html 104. Yap AU, Lye KW, Sau CW (1997) Surface characteristics of tooth-colored
restoratives polished utilizing different polishing systems. Oper Dent 22, 260-265. 105. Ergucu Z, Turkun LS, Aladag A (2007) Color stability of nanocomposites
polished with one-step systems. Oper Dent 33, 413-420. 106. Kakaboura A, Fragouli M, Rahiotis C, Silikas N (2007) Evaluation of surface
characteristics of dental composites using profilometry, scanning electron, atomic force microscopy and gloss-meter. J Mater Sci Mater Med 18, 155-163.
107. Filho, J.D.N., et al., Degree of conversion and plasticization of dimethacrylate-based polymeric matrices: Influence of light-curing mode. Journal of Oral Science, 2008. 50(3): p. 315-321.
108. Emani, M. and K.J.M. Soderholm, How light irradiance and curing time affect monomer conversion in light-cured resin composites. European Journal of Oral Science, 2003. 111: p. 536-542.
109. Charlton, D.G., et al., Comparison of two video-imaging instruments for measuring volumetric shrinkage of dental resin composites. Journal of Dentistry, 2005. 33(9): p. 757-763.
110. 106de Gee, A.J., C. Davidson, and A. Smith, A modified dilatometer for continuous recording of volumetric polymerization shrinkage of composite restorative materials. Journal of Dentistry, 1981. 9: p. 36-42.
111. Penn, R., A recording dilatometer for measuring polymerization shrinkage. Dental Materials, 1986. 2: p. 78-79.
112. Suliman, A., D. Boyer, and R. Lakes, Polymerization shrinkage of composite resins: comparison with tooth deformation. Journal of Prosthetic Dentistry, 1994. 71: p. 7-12.
113. De Gee, A.J., A.J. Feilzer, and C.L. Davidson, True linear polymerization shrinkage of unfilled resins and composites determined by a linometer. Dental Materials, 1993. 9: p. 11-14.
114. Labella, R., et al., Polymerization shrinkage and elasticity of flowable composites
![Page 94: EFFECT OF DIFFERENT PERCENTAGES OF SILICA NANOFIBERS … · 2019. 6. 5. · COMPOSITE RESINS. by . SHASHIKANT SINGHAL . JOHN O. BURGESS (CHAIR) AMJAD JAVED . DENIZ CAKIR-USTUN . JACK](https://reader034.fdocuments.in/reader034/viewer/2022052016/602ec33c12076076c3493603/html5/thumbnails/94.jpg)
80
and filled adhesives. Dental Materials, 1999(15): p. 128-137. 115. J.S, R. and P.H. Jacobsen, The polymerization shrinkage of composite resins.
Dental Materials, 1989. 5: p. 41-44. 116. Lambrechts, P., et al., How to simulate wear? Overview of existing methods.
Dental Materials, 2006. 22(8): p. 693-701 117. Schindler, H.J., E. Stengel, and W.E.L. Spiess, Feedback control during
mastication of solid food textures--a clinical-experimental study. The Journal of Prosthetic Dentistry, 1998. 80(3): p. 330-336.
118. Teoa, W.-E., et al., A dynamic liquid support system for continuous electrospun yarn fabrication. Polymer, 2007. 48(12): p. 3400-3405.
119. Wang Peng-Fei, D.S.-J.Z.W.Z.J.-Y.W.J.-T. and W. Lee William, FTIR Characterization of Fluorine Doped Silicon Dioxide Thin Films Deposited by Plasma Enhanced Chemical Vapor Deposition. Chinese Physics Letters, 2000. 17(12): p. 912.
120. Bayramgil, N.P., Thermal degradation of [poly (N-vinylimidazole)-polyacrylic acid] interpolymer complexes. Polymer Degradation and Stability, 2008. 93(8): p. 1504-1509.
121. Sung-seen Choi et al. Silica nanofibers from electrospinning/sol-gel process. Journal of material science letters 22,2003,891-893.
122. Silva, E.M.d., et al., Relationship between the degree of conversion, solubility and salivary sorption of a hybrid and a nanofilled resin compositeinfluence of the light-activation mode. Journal of Applied Oral Science, 2008. 16(2): p. 161-166.
123. Halvorson, R.H., R.L. Erickson, and C.L. Davidson, The effect of filler and silane content on conversion of resin-based composite. Dental Materials, 2003. 19: p. 327-333.
124. Arikawa, H., et al., Light transmittance characteristics of light-cured composite resins. Dental Materials, 1998. 14(6): p. 405-411.
125. Ming, T., et al., Fabrication and evaluation of Bis-GMA/TEGDMA dental resins/composites containing nano fibrillar silicate. Dental Materials, 2008. 24: p. 235–243.
126. Askeland, D.R. and P.P. Phulé, The Science and Engineering of Materials. Fifth ed. 2006: Thomson.
127. Atkins, A.G. and Y.W. Mai, Elastic and Plastic Fracture: metals, polymers, ceramics, composites, biological materials 1985. p48, 49.