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Author(s): Vanessa Sousa, Nikos Mardas, Dave Spratt, Iman A. Hassan, Nick J. Walters, Víctor 
Beltrán & Nikolaos Donos 
Title: The Effect of Microcosm Biofilm Decontamination on Surface Topography, 
Chemistry, and Biocompatibility Dynamics of Implant Titanium Surfaces 
Year: 2022 
Version: Published version 
Copyright:   The Author(s) 2022 
Rights: CC BY 4.0 
Rights url: http://creativecommons.org/licenses/by/4.0/ 
 
Please cite the original version: 
Sousa, V.; Mardas, N.; Spratt, D.; Hassan, I.A.; Walters, N.J.; Beltrán, V.; Donos, N. The Effect of 
Microcosm Biofilm Decontamination on Surface Topography, Chemistry, and Biocompatibility 
Dynamics of Implant Titanium Surfaces. Int. J. Mol. Sci. 2022, 23, 10033. 
https://doi.org/10.3390/ijms231710033 
Citation: Sousa, V.; Mardas, N.;
Spratt, D.; Hassan, I.A.; Walters, N.J.;
Beltrán, V.; Donos, N. The Effect of
Microcosm Biofilm Decontamination
on Surface Topography, Chemistry,
and Biocompatibility Dynamics of
Implant Titanium Surfaces. Int. J.
Mol. Sci. 2022, 23, 10033. https://
doi.org/10.3390/ijms231710033
Academic Editor: Lia Rimondini
Received: 1 August 2022
Accepted: 16 August 2022
Published: 2 September 2022
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Attribution (CC BY) license (https://
creativecommons.org/licenses/by/
4.0/).
 International Journal of 
Molecular Sciences
Article
The Effect of Microcosm Biofilm Decontamination on Surface
Topography, Chemistry, and Biocompatibility Dynamics of
Implant Titanium Surfaces
Vanessa Sousa 1,* , Nikos Mardas 2, Dave Spratt 3, Iman A. Hassan 4, Nick J. Walters 5 , Víctor Beltrán 6
and Nikolaos Donos 2
1 Periodontology and Periodontal Medicine, Centre for Host-Microbiome Interactions, Faculty of Dentistry,
Oral and Craniofacial Sciences, Kings College London, Guy’s and St Thomas’ NHS Foundation Trust,
London SE1 9RT, UK
2 Centre for Oral Clinical Research, Centre for Oral Immunobiology & Regenerative Medicine,
Institute of Dentistry, Barts and The London School of Medicine and Dentistry, Queen Mary University London,
London E1 2AD, UK
3 Microbial Diseases, Eastman Dental Institute, University College London, London WC1E 6BT, UK
4 Materials Chemistry Centre, Department of Chemistry, University College London, 20 Gordon Street,
London WC1H 0AJ, UK
5 Natural Resources Institute Finland, Latokartanonkaari 9, 00790 Helsinki, Finland
6 Clinical Investigation and Dental Innovation Center, Dental School and Center for Translational Medicine,
Universidad de La Frontera, Temuco 4780000, Chile
* Correspondence: vanessa.sousa@kcl.ac.uk
Abstract: Since the inception of dental implants, a steadily increasing prevalence of peri-implantitis
has been documented. Irrespective of the treatment protocol applied for the management of peri-
implantitis, this biofilm-associated pathology, continues to be a clinical challenge yielding unpre-
dictable and variable levels of resolution, and in some cases resulting in implant loss. This paper
investigated the effect of microcosm biofilm in vitro decontamination on surface topography, wetta-
bility, chemistry, and biocompatibility, following decontamination protocols applied to previously
infected implant titanium (Ti) surfaces, both micro-rough -Sandblasted, Large-grit, Acid-etched
(SLA)-and smooth surfaces -Machined (M). Microcosm biofilms were grown on SLA and M Ti discs.
These were treated with TiBrushes (TiB), combination of TiB and photodynamic therapy (PDT),
combination of TiB and 0.2%CHX/1%NaClO, plus or minus Ultraviolet-C (UV-C) radiation. Surface
topography was evaluated by Scanning Electron Microscopy (SEM) and Laser Surface Profilometry.
Surface function was analysed through wettability analysis. Surface chemistry evaluation of the
discs was performed under SEM/Energy-dispersive X-ray spectroscopy (EDX) and X-ray photo-
electron spectroscopy (XPS). Biocompatibility was tested with the cytocompatibility assay using
human osteoblast-like osteosarcoma cell line (MG-63) cells. Elemental analysis of the discs disclosed
chemical surface alterations resulting from the different treatment modalities. Titanium, carbon,
oxygen, sodium, aluminium, silver, were identified by EDX as the main components of all the discs.
Based on the data drawn from this study, we have shown that following the decontamination of
Ti surfaces the biomaterial surface chemistry and topography was altered. The type of treatment
and Ti surface had a significant effect on cytocompatibility (p = 0.0001). Although, no treatment
modality hindered the titanium surface biocompatibility, parameters such as the use of chemical
agents and micro-rough surfaces had a higher cytotoxic effect in MG-63 cells. The use of smooth
surfaces, and photofunctionalisation of the TiO2 layer had a beneficial effect on cytocompatibility
following decontamination.
Keywords: peri-implantitis; decontamination; therapy; UV-C; photodynamic therapy; titanium
Brush; biocompatibility; XPS; EDX
Int. J. Mol. Sci. 2022, 23, 10033. https://doi.org/10.3390/ijms231710033 https://www.mdpi.com/journal/ijms
Int. J. Mol. Sci. 2022, 23, 10033 2 of 15
1. Introduction
The use of dental implants in everyday clinical practice is increasing, and considered
to be one of the most successful treatments for the restoration of missing teeth [1,2]. How-
ever, over the years, the prevalence of biological complications has been increasing [3]
and peri-implant diseases have become a clinical reality [4]. Peri-implantitis is a plaque-
associated pathological condition occurring in tissues around dental implants, characterised
by inflammation and progressive loss of supporting bone [5]. Notably, peri-implantitis
stands as a prevailing clinical challenge not only due to the complex and dynamic biofilm
ecosystem colonising the implant surface and its interplay with the host, but also due to the
burdensome decontamination process of the contaminated implant fixture and consequent
biomaterial alteration [6].
Different non-surgical and surgical solutions have been advocated for the treatment of
peri-implantitis [7–11]. The successful clinical management of peri-implantitis is based on
the evaluation of composite therapeutic end-points, that correspond to disease resolution.
These include the clinical presence of shallow pockets, without bleeding-on-probing (BoP)
and/or suppuration, and the maintenance of radiographic bone levels [12]. However,
current forms of treatment for peri-implantitis are often inadequate and may result in
implant loss [4,13,14]. As there is no consensus on a gold-standard protocol of care, nor any
universally accepted recommendations, the treatment of peri-implantitis remains a clinical
challenge [4,9].
Notably, in the search of enhanced hard tissue integration, a number of implant surface
modifications [1] have been implemented throughout the past half-century [5,15]. These
different surfaces exhibit a range of Ra values, ranging from 0.10 µm (machined surfaces),
to 6 µm (rough surfaces) [16]. Although only a few studies provided data on the suscepti-
bility to the development of peri-implantitis due to implant surface topography [17–21],
implants with modified surfaces may show a higher susceptibility to peri-implant disease
re-infection [22]. Moreover, remnants of debris (organic or inorganic), or alterations of the
implant surface [23] following a range of decontamination therapies, may trigger a number
of soft and hard tissue healing responses [24]. Therefore, it seems plausible that protocols
for surface decontamination may have different effects based on the macro- and micro
topography of the surface [25]. Whilst the elimination of the bacterial pathogens and their
remnants is vital for clinical stable implant outcomes, implant surface biocompatibility,
initial severity of disease and defect morphology may influence the outcome for certain
therapies [26].
The implant surface properties such as topography, chemistry, and biocompatibil-
ity, have been extensively investigated in early osseointegration and prevention of early
implant failure [1,27–30]. However, the effect of decontamination treatment on these sur-
face properties are still poorly understood. This research provides an evaluation of the
changes of sole or combination decontamination protocols (Ti brush, photodynamic ther-
apy, 0.2%CHX/1%NaClO, and UV-C irradiation) on the Machined (M) and Sandblasted,
Large-grit, Acid-etched (SLA) implant surfaces, and their resultant biomaterial surface
topography, wettability, chemistry and biocompatibility following the application of these
decontamination protocols.
2. Results
Different disinfection protocols (Table 1) were evaluated to understand factors altering
the Ti surface characteristics following disinfection of M and SLA Ti surfaces.
Int. J. Mol. Sci. 2022, 23, 10033 3 of 15
Table 1. Distribution of the experimental and control groups.
Control Groups * Experimental Surface Disinfection Protocols * ˆ a
Biofilm (MC) a TiB (T1)
Irradiation c
TiB+ (T1+)
Sterile (SC) TiB+PDT (T2) TiB+PDT+ (T2+)
Sterile autoclaved (SA) TiB+CA (T3) TiB+CA+ (T3+)
Biofilm+ (MC+)
SA+ (SA+)
SC+ (SC+)
* Machined and SLA substrata were used in all groups (n = 3). ˆ For the cytocompatibility assay the same
control and experimental protocols were used following steamed heat autoclaved (A) at 121 ◦C/15 min. a Intact
30-day steady-state biofilms were used. c Exposure for 60 min to a source of standardised UV-C irradiation prior
to testing.
2.1. Viable Biofilm Quantification
2.1.1. Machined Ti Surfaces
In M surfaces the undisturbed microcosm biofilm (MC) group showed a total viable
count of anaerobic spp. and aerobic spp. of 8.74log10 CFU/mL (95%CI: 8.51-8.97log10 CFU/mL)
and 8.40log10 CFU/mL (95%CI: 8.17-8.63log10 CFU/mL) respectively. In comparison to the
MC group, the anaerobic (3.48log10 CFU/mL) and aerobic (3.43log10 CFU/mL) spp. decreased
significantly (p = 0.001) in the MC+. After mechanical disruption alone (T1) of the steady-
state 30-day peri-implantitis biofilm, anaerobic spp. (2.84log10 CFU/mL) and aerobic spp.
(2.82log10 CFU/mL) were present. The groups involving combination therapy (T2, T3) and
either mechanical or combination therapy plus UV-C irradiation (T1+, T2+, T3+) were not
significantly different from the control sterile groups (p = 0.0001), yielding undetectable
live bacterial counts.
2.1.2. SLA Ti Surfaces
Anaerobic spp. (8.93log10 CFU/mL [95%CI: 8.55–9.29log10 CFU/mL]) over-represented
the viable log10 CFU/mL in the MC group. In comparison to the untreated 30-day steady-
state biofilms (MC), overall, the anaerobic and aerobic spp. decreased by ca. 2.57log10
CFU/mL in the MC+ group. Following mechanical therapy alone the aerobic spp., and
anaerobic spp. showed a decrease of 5.44log10 CFU/mL and 5.82log10 CFU/mL respectively
in comparison to the MC group. The groups involving combination therapy (T2, T3) and
either mechanical or combination therapy plus UV-C irradiation (T1+, T2+, T3+) were not
significantly different from the sterile control groups (p = 0.0001), yielding undetectable
live bacterial counts.
All autoclaved groups (control and experimental groups) yielded undetectable live
bacterial counts.
2.2. Surface Topography, Wettability, Chemistry and Biocompatibility
2.2.1. SEM Imaging Ti Surfaces before and after Decontamination
A qualitative assessment was conducted before and after employing a number of
decontamination protocols on SLA and M substrata. SEM images of the SC group confirmed
the evident different configuration of M and SLA surfaces.
Groups MC, T1, T2 and T3 showed similar qualitative surface characteristics in com-
parison to their UV-C irradiated counterparts (MC+, T1+, T2+, T3+, respectively). In
addition, SC was similar to SC+, SA, and SA+.
The SEM analysis of the MC group revealed a biofilm structure fully covering the Ti
surface. It was observed that once the SLA and M surfaces are covered by a microcosm
biofilm, it is not possible to differentiate between surfaces.
Following cleansing of the implant surfaces, remaining bacteria was found in all
cases (Figure 1). It is evident that the use of a TiB for mechanical therapy will modify the
surface topography of the Ti surface. For instance, SLA surfaces exhibited a combination of
flattened areas combined with the typical SLA rough characteristics, whereas M surfaces
Int. J. Mol. Sci. 2022, 23, 10033 4 of 15
exhibited scratches throughout the cleaned surface. Therefore, debris was present across
the cleaned surfaces. Besides the organic bacterial remnants, this debris may correspond to
detached abraded Ti particles or to the precipitation of crystals formed through the use of
coadjutant chemical agents, such as PBS.
Int. J. Mol. Sci. 2022, 23, x FOR PEER REVIEW 4 of 16 
 
 
The SEM analysis of the MC group revealed a biofilm structure fully covering the Ti 
surface. It was observed that once the SLA and M surfaces are covered by a microcosm 
biofilm, it is not possible to differentiate between surfaces. 
Following cleansing of the implant surfaces, remaining bacteria was found in all 
cases (Figure 1). It is evident that the use of a TiB for mechanical therapy will modify the 
surface topography of the Ti surface. For instance, SLA surfaces exhibited a combination 
of flattened areas combined with the typical SLA rough characteristics, whereas M sur-
faces exhibited scratches throughout the cleaned surface. Therefore, debris was present 
across the cleaned surf c s. Besides the organic b cteri l remnants, this debris may corre-
spond to detached abra ed Ti part cles or to the precipitation of crystals for e  gh 
the use of coadjutant chemical agents, such as PBS.  
 
Figure 1. Scanning electron microscopy images showing (a) MC biofilm grown on top of Ti M sub-
strata (scale bar = 5 µm, magnification 5000×), and (b) M Ti surfaces following disinfection employ-
ing T1 (scale bar = 2 µm, magnification 10,000×). 
2.2.2. Surface Roughness 
The roughness (Ra) of each substrate before and after experimental therapy was an-
alysed by laser profilometry with the results shown in Figure 2 (MC, T1, T2, T3, SA, SC, 
MC+, T1+, T2+, T3+, SA+, SC+). The SLA substrate (2.87±0.04um) was found to have the 
highest Ra value, which was, significantly rougher compared to M (0.50±0.007um) (p = 
0.000). Contrary to SLA surfaces, following mechanical therapy the Ra increased in M 
substrata (p = 0.000). Although Ra values decreased in mechanically treated SLA surfaces, 
these substrata remained with the highest Ra values (p = 0.000) before and after therapy. 
The UV-C irradiated groups T1+, T2+, T3+, SA+, SC+, showed significantly (p = 0.000) de-
creased Ra values, whilst non-UV-C irradiated groups (T1, T2, T3, MC, SA, SC) were 
found significantly rougher (p = 0.000). 
 
(a) (b) 
(a) (b) 
Figure 1. Scanning electron microscopy images showing (a) MC biofilm grown on top of Ti M
substrata (scale bar = 5 µm, magnification 5000×), and (b) M Ti surfaces ollowing disinfection
employin T1 (scale bar = 2 µm, magnification 10,000×).
2.2.2. Surface Roughness
The roughness (Ra) of each substrate before and after experimental therapy was
analysed by laser profilometry with the results shown in Figure 2 (MC, T1, T2, T3, SA, SC,
MC+, T1+, T2+, T3+, SA+, SC+). The SLA substrate (2.87±0.04um) was found to have
the highest Ra value, which was, significantly rougher compared to M (0.50 ± 0.007um)
(p = 0.000). Contrary to SLA surfaces, following mechanic l therapy the Ra incr ased in M
substrata (p = 0.000). Although Ra values decreased in mechanically treated SLA surfaces,
these substrata remained with the highest Ra values (p = 0.000) before and after therapy.
The UV-C irradiated groups T1+, T2+, T3+, SA+, SC+, showed significantly (p = 0.000)
decreased Ra values, whilst non-UV-C irradiated groups (T1, T2, T3, MC, SA, SC) were
found significantly rougher (p = 0.000).
Int. J. Mol. Sci. 2022, 23, x FOR PEER REVIEW 2 of 4 
 
 
 27 
 28 
 29 
 30 
Figure 2. Surface roughness values of M and SLA topographies across control and 31 
experimental protocols -/+ UVC irradiation (n= 3). Each circle represents the mean and 32 
error bars the 95%CI. 33 
 34 
 35 
 36 
 37 
 38 
 39 
 40 
 41 
 42 
Figure 3. Contact angle of ddH2O on M (a) and SLA (b) substrate across control and 43 
experimental protocols +/- UVC irradiation. Each circle represents the mean and error bars 44 
the 95%CI (n= 3). 45 
 46 
 47 
 48 
 49 
 50 
 
 
 
 
c d 
(a) (b) 
 
 
 
(a) (b) 
Figure 2. Surface roughness values of Machined and SLA topographies across (a) control (MC, SA,
SC) and (b) experimental (T1, T2, T3) protocols −/+ UVC irradiation (n = 3). Each circle represents
the mean and error bars the 95% CI.
2.2.3. ddH2O Contact Angles
The photo-reactivity of the Ti discs was analysed by examining the ddH2O contact
angle on the substrate following exposure to UV-C light before and after experimental
decontamination of the substrata.
Int. J. Mol. Sci. 2022, 23, 10033 5 of 15
As shown in Figure 3 the most hydrophobic of the analysed samples was SC (SLA)
(127.38 ± 0.323◦). T1 (M) was shown to be the most hydrophilic group (27.05 ± 0.348◦),
followed by T3+ and T2+ (39.54 ± 2.19◦), which were not significantly different from
SC+ (i.e., sterile disc + UV-C irradiation) and SA+ (i.e., sterile disc + autoclaving + UV-C
irradiation) (p = 1.00) in SLA substrata. UV-C irradiation had a higher effect on decreasing
the contact angles in SLA in comparison to M substrata. In M substrata, the groups that
included mechanical therapy and adjunct UV-C irradiation in their protocols (T1+, T2+,
T3+) and groups T1 and T2, decreased their contact angles in comparison to control SA/+,
SC/+ (p = 0.000).
Int. J. Mol. Sci. 2022, 23, x FOR PEER REVIEW 2 of 4 
 
 
 27 
 28 
 29 
 30 
Figure 2. Surface roughness values of M and SLA topographies across control and 31 
experimental protocols -/+ UVC irradiation (n= 3). Each circle represents the mean and 32 
error bars the 95%CI. 33 
 34 
 35 
 36 
 37 
 38 
 39 
 40 
 41 
 42 
Figure 3. Contact angle of ddH2O on M (a) and SLA (b) substrate across control and 43 
experimental protocols +/- UVC irradiation. Each circle represents the mean and error bars 44 
the 95%CI (n= 3). 45 
 46 
 47 
 48 
 49 
 50 
 
 
 
 
c d 
(a) (b) 
 
 
 
(a) (b) 
Figure 3. Contact angle of ddH2O on Machined (a) and SLA (b) substrate across control (MC, SA,
SC) and experimental (T1, T2, T3) protocols +/− UVC irradiation. Each circle represents the mean
and error bars the 95% CI ( = 3).
2.2.4. Surface Chemistry
Titanium (Ti), carbon (C), oxygen (O), sodium (Na), aluminium (Al), and silver (Ag)
were identified by SEM/EDX as the main components of all the discs (Figure 4). Interest-
ingly, small percentages of Nitrogen (N), vanadium (V), calcium (Ca), potassium (K) and
chloride (Cl) were also detected, Figure 4 summarises the elements found. However, Ti was
the only element found in the SC and SA groups. XPS analyses showed that cleaning proce-
dures have an effect on the Ti oxide layer (TiO2) surface properties. X-ray photoelectron
spectroscopy high resolution scans (Figure 5) detected peaks for Al(2p), Ca(2p) and N(1s).
Int. J. Mol. Sci. 2022, 23, x FOR PEER REVIEW 3 of 4 
 
 
 51 
Figure 4. Results of SEM/EDX analysis, overview on mean atomic percentage (at. %) 52 
of elements on M (a) and SLA (b) implant surfaces before and after disinfection.   53 
 54 
 55 
 56 
 57 
 58 
Figure 5. Effect of cleaning procedures on the Ti oxide layer (TiO2) surface properties. 59 
X-ray photoelectron spectroscopy high resolution scans detected peaks for Al(2p), Ca(2p) 60 
and N(1s). Samples were sputtered using a 2kV argon ion gun; the sputtering rate was 1 61 
angstrom per second.  62 
 63 
 64 
 65 
Figure 6. Evaluation of human osteoblast-like osteosarcoma cell line (MG-63) (left) 66 
proliferation across experimental treatments on M and SLA substrata (n= 3). The UVC 67 
irradiated substrate (right) (in T1+, T2+, T3+, SA+, SC+) was shown to have a greater cell 68 
proliferation (n= 3) (p= 0.0001). 69 
 70 
 71 
 
 
 
(a) (b) 
 
 
 
 
 
 
 (a) (b) 
Figure 4. Results of SEM/EDX analysis, overview on mean atomic percentage (at. %) of elements on
Machined (a) and SLA (b) implant surfaces before (MC, SA, SC) and after (T1, T2, T3) disinfection.
Int. J. Mol. Sci. 2022, 23, 10033 6 of 15
Int. J. Mol. Sci. 2022, 23, x FOR PEER REVIEW 6 of 16 
 
 
 
Figure 4. Results of SEM/EDX analysis, overview on mean atomic percentage (at. %) of elements on 
Machined (a) and SLA (b) implant surfaces before (MC, SA, SC) and after (T1, T2, T3) disinfection. 
 
Figure 5. Effect of cleaning procedures on the Ti oxide layer (TiO2) surface properties. X-ray photo-
electron spectroscopy high resolution scans detected peaks for Al(2p), Ca(2p) and N(1s). Samples 
were sputtered using a 2 kV argon ion gun; the sputtering rate was 1 angstrom per second. 
2.2.5. Cytocompatibility of Decontaminated Ti Surfaces 
The cell proliferation of human osteoblast-like osteosarcoma cell line (MG-63) was 
examined over one week by employing the alamar blue assay. At day 1 SLA substrata 
exhibited higher cell proliferation. However, there was a higher cell proliferation in M 
substrata at a later stage on day 4 and 7. Overall, a higher number of cells was found at 
day 7 compared to day 1 (SLA and M surfaces). The proliferation of MG-63 seems to be 
affected by the employed experimental treatment (Figure 6). The lowest cell proliferation 
was found in the group MCA, whilst the combination therapies were not significantly 
different in terms of cell proliferation, the SA+ yielded the highest cell numbers (1.84 × 105, 
95% CI: 1.58 × 105 – 2.09 × 105) and was not significantly different from both SC+ and T1+. 
An interaction between treatment and surface was also observed (Figure 6). The prolifer-
ation of MG-63 seemed to be positively affected by UV-C irradiation. Groups T1A+, T2A+, 
T3A+, SA+, SC+, shown to have a greater cell proliferation in comparison to non-irradiated 
groups (T1A, T2A, T3A, SA, SC). 
(a) (b) 
Figure 5. Effect of cleaning procedures on the Ti oxide layer (TiO2) surface properties. X-ray photo-
electron spectroscopy high resolution scans detected peaks for Al(2p), Ca(2p) and N(1s). Samples
were sputtered using a 2 kV argon ion gun; the sputtering rate was 1 angstrom per second.
2.2.5. Cytocompatibility of Decontaminated Ti Surfaces
The cell proliferation of human osteoblast-like osteosarcoma cell line (MG-63) was
examined over one week by employing the alamar blue assay. At day 1 SLA substrata
exhibited igher cell prolifer tion. Howev r, there was a higher c ll proliferation in M
substrata at a later stage on day 4 and 7. Overall, a higher number of cells was found at
day 7 compared to day 1 (SLA and M surfaces). The proliferation of MG-63 seems to be
affected by the employed experimental treatment (Figure 6). The lowest cell proliferation
was found in the group MCA, whilst the combination therapies were not significantly
different in terms of cell proliferation, the SA+ yielded the highest cell numbers (1.84 × 105,
95% CI: 1.58 × 105 – 2.09 × 105) and was not significantly different from both SC+ and
T1+. An interaction between treatment and surface was also observed (Figure 6). The
proliferation of MG-63 s emed to be p sitively affected by UV-C irradiation. Groups
T1A+, T2A+, T3A+, SA+, SC+, shown to have a greater cell proliferation in comparison to
non-irradiated groups (T1A, T2A, T3A, SA, SC).
Int. J. Mol. Sci. 2022, 23, x FOR PEER REVIEW 3 of 4 
 
 
 51 
Figure 4. Results of SEM/EDX analysis, overview on mean atomic percentage (at. %) 52 
of elements on M (a) and SLA (b) implant surfaces before and after disinfection.   53 
 54 
 55 
 56 
 57 
 58 
Figure 5. Effect of cleaning procedures on the Ti oxide layer (TiO2) surface properties. 59 
X-ray photoelectron spectroscopy high resolution scans detect d peaks for Al(2p), Ca(2p) 60 
and N(1s). Samples were sputtered using a 2kV argon ion gun; the sputtering rate was 1 61 
angstrom per second.  62 
 63 
 64 
 65 
Figure 6. Evaluation of human osteoblast-like osteosarcoma cell line (MG-63) (left) 66 
proliferation across experimental treatments on M and SLA substrata (n= 3). The UVC 67 
irradiated substrate (right) (in T1+, T2+, T3+, SA+, SC+) was shown to have a greater cell 68 
proliferation (n= 3) (p= 0.0001). 69 
 70 
 71 
 
 
 
(a) (b) 
 
 
 
 
 
 
 (a) (b) 
Figure 6. Evaluation of human osteoblast-like osteosarcoma cell line (MG-63) (a) proliferation across
experimental treatments on Machined and SLA substrata (n = 3). The UVC-irradiated substrate (b) (in
T1+, T2+, T3+, SA+, SC+) was shown to have a greater cell proliferation (n = 3) (p = 0.0001).
2.2.6. SEM and CLSM Imaging of MG-63
The MG-63 cells were visualised under CLSM microscopy across all treatment modali-
ties and at day 7 of incubation (Figure 7). In this experiment, the cells were found to grow
on all treated surfaces. No qualitative morphological differences were observed.
Int. J. Mol. Sci. 2022, 23, 10033 7 of 15
Int. J. Mol. Sci. 2022, 23, x FOR PEER REVIEW 7 of 16 
 
 
 
Figure 6. Evaluation of human osteoblast-like osteosarcoma cell line (MG-63) (a) proliferation across 
experimental treatments on Machined and SLA substrata (n = 3). The UVC-irradiated substrate (b) 
(in T1+, T2+, T3+, SA+, SC+) was shown to have a greater cell proliferation (n = 3) (p = 0.0001). 
2.2.6. SEM and CLSM Imaging of MG-63 
The MG-63 cells were visualised under CLSM microscopy across all treatment mo-
dalities and at day 7 of incubation (Figure 7). In this experiment, the cells were found to 
grow on all treated surfaces. No qualitative morphological differences were observed. 
 
Figure 7. (a) Composite xy view CLSM image of MG-63 cells showing nucleus in green and actin 
filaments of the cytoskeleton in red grown on top of a disinfected M surface T2A+ group (scale bar 
= 30 µm). (b) SEM image of M surface T2A (scale bar = 5 µm, magnification 6500×). 
3. Discussion 
Although an important part of the peri-implantitis treatment pathway is the decon-
tamination of the implant surface [7,9,23], the effect of decontamination protocols on den-
tal implants derived from peri-implantitis sites is poorly understood. The evidence has 
reported that no surface decontamination method (e.g., Ti curettes, plastic curettes, Ti 
brushes, air-powder abrasives, laser application or implantoplasty) appear to yield supe-
rior outcomes to any other [26,31,32], and that there is no consensus on a standard protocol 
for the clinical treatment of peri-implantitis [33]. In the present research we have shown 
the associations of different in vitro decontamination protocols to the physico-chemical 
composition and the biocompatibility outcomes of M and SLA titanium surfaces before 
and after decontamination, and their consequent advantages and disadvantages are dis-
cussed below in light of their associations with specific outcomes.  
  
(a) (b) 
(a) (b) 
Figure 7. (a) Composite xy view CLSM image of MG-63 cells showing nucleus in green and
actin filaments of the cytoskeleton in red grown on top of a disinfected M surface T2A+ group
(scale bar = 30 µm). (b) SEM image of M surface T2A (scale bar = 5 µm, magnification 6500×).
3. Discussion
Although an important part of the peri-implantitis treatment pathway is the decon-
tamination of the i plant surface [7,9,23], the effec of decontamination protocols
dental implan s derived from p ri-implantitis sites is poorly understood. The evidence
h s re orted that no surface decontamination method (e.g., Ti curettes, plastic curett s, Ti
brushes, air-powder abrasiv s, laser application or implantoplasty) appear to yield superior
outcomes to any other [26,31,32], and that there is no co sensus on a standard protocol
for the clinical treatment of peri-implantitis [33]. In the present research we have shown
the associations of different in vitro decontamination protocols to the physico-chemical
composition and the biocompatibility outcomes of M and SLA titanium surfaces before and
after decontamination, and their consequent advantages and disadvantages are discussed
below in light of their associations with specific outcomes.
3.1. Viable Biofilm Quantification
A significant decrease (p = 0.001) in the CFU/mL viable counts were observed in
all experimental groups in comparison to MC. Importantly, only groups MC+ and T1
had detectable live bacteria left behind. In the remaining groups T1+, T2-/+, and T3-/+
no live bacteria were recovered. Both surfaces yielded similar counts of viable bacterial
remnants. The affinity of Staphylococci spp. to Ti surfaces has been documented in a number
of studies [34,35]. Higher abundances of S. aureus have also been associated with peri-
implantitis [36]. The success of antimicrobial therapy for peri-implantitis is often rated
according to the bacterial load that can be found after treatment [37,38]. As previously
mentioned, it is evident that mechanical disruption of the biofilm alone is not sufficient
to eliminate the complex live bacterial consortia from the Ti discs and these findings are
consistent with the current evidence [39,40]. Therefore, it is important that combination
decontamination protocols are employed for the elimination of viable bacteria within
peri-implantitis associated biofilms.
3.2. Surface Topography, Wettability, Chemistry and Biocompatibility
3.2.1. SEM Imaging and Surface Roughness of Ti Surfaces before and after Decontamination
This investigation showed by SEM imaging analysis of the experimental surfaces
that bacteria were often observed positioned in the SLA crates and micropits, thus these
irregularities seem to be forming an ideal niche for the live bacterial remnants. It is
expected that these areas could act as reservoirs and germination nuclei for the bacteria
and most importantly, they may be protected from the action of any employed chemical
or antibiotic agents. This is fundamental to clinical practice, as our study showed that
mechanical therapy of Machined surfaces also resulted in an increased number of Ti
Int. J. Mol. Sci. 2022, 23, 10033 8 of 15
surface irregularities “scratches”, which according to our biofilm quantification outcomes,
increased Ti surface irregularities will result in higher bacterial accumulation and facilitation
of biofilm formation.
The Ra value is one of the most common indicators to characterise surface roughness.
However, it has been reported that the Ra parameter captures the surface topography in
one direction and bias may be introduced by the profilometer [41]. In the present study,
non-threaded Ti discs were used, thus enabling an accurate roughness evaluation. However,
as Ti discs were employed instead of entire dental implants, the macro and microstructure
of the screw models may be differently affected by the surface treatments as compared to
the discs [42]. The use of mechanical therapy by means of a TiB resulted in the increase of Ra
values for M surfaces. Conversely, and in agreement with a previous study [43] mechanical
therapy of SLA surfaces resulted in a decrease of the surface roughness Ra parameters. The
roughness and free surface energy of dental implant surfaces may influence the colonisation
of bacteria [44]. However, it has been reported that a threshold value of Ra 0.2 µm does not
impact the total amount of plaque of the colonizing bacteria [45]. In the present study, the
lowest Ra value was observed in the SA+ (Ra = 0.34 µm) and SC+ (Ra = 0.37 µm) groups,
followed by the group T2+ (Ra = 0.62 µm) in M surfaces. Therefore, the use of TiB will yield
a surface roughness over the aforementioned threshold value, which may pose a benefit
due to the reduction of surface roughness and the consequent elimination of organic debris.
An alternative to smoother surfaces may be achieved by implantoplasty, however, that
technique is out of the scope of the present study and warrants further investigation due
to the side effects (e.g., implant fracture, release of Ti particles locally/systemically) that
technique may convey [46,47].
3.2.2. ddH2O Contact Angles
The present study investigated the photofunctionalisation of the TiO2 layer of the
employed Ti discs by UV-C irradiation. This phenomenon, UV photofunctionalisation,
converts the material from hydrophobic to super-hydrophilic (i.e., water contact angle
of <5◦) via surface irradiation. This process has been reported to be capable to improve the
cellular response [48], as well as to reverse the effects of the time dependent degradation
of biomaterial osteoconductivity [49]. It is assumed that upon UV irradiation, T4+ sites
are converted to Ti3+ sites and in doing so, oxygen vacancies are formed at bridging sites
which are more favourable for dissociative water adsorption [50,51]. In addition, UV photo-
functionalisation has been reported to have a bactericidal and detoxifying effect [51–53],
and to enhance cellular adhesion markers on various Ti substrata [54]. In the present study,
the UV-C irradiated substrata, exhibited a decreased contact angle. Notably, SLA surfaces
resulted in lower contact angles than M surfaces following irradiation. It seems that the
use of TiB plus UV-C irradiation tends to decrease the contact angles and in consequence
to a more hydrophilic implant surface. Furthermore, in non-UV-C irradiated samples,
a decrease in contact angles was observed in TiB (T1) group in SLA and M substrata.
3.2.3. Surface Chemistry
Additionally, after UV photofunctionalisation on the Ti, the charge of the substrate is
changed from electronegative to electropositive, which enhances protein adsorption [54].
In the present study, the EDX analyses showed that UV-C irradiated surfaces had a higher
Oxygen (O) at. % and a lower Carbon (C) at. % compared to the non-UV-C irradiated
surfaces. A high C at. % was observed in the MC group, it is likely that the C source
comes from the organic bacterial debris left behind after treatment. In addition, another
important source of C may be introduced by the technique itself (for example, C content of
the environment) and by the progressive deposition of hydrocarbons onto Ti surfaces [55].
Furthermore, a small Vanadium (V) at.% (i.e., 0.53) was observed, and this confirms the
grade 5 according to Ti classification. In addition, remnants of Silver (Ag), Chlorine (Cl),
and Sodium (Na) were observed in group T3 in SLA surfaces. Na was also present in
groups T2 (TiB+PDT) and T1 (TiB) (SLA). Therefore, it is plausible that these inorganic
Int. J. Mol. Sci. 2022, 23, 10033 9 of 15
remnants arise from the decontamination treatment modality employed and may provide
a negative influence the re-osseointegration process [51].
3.2.4. Cytocompatibility of Decontamination Ti Surfaces
Ti has been widely used as an implant material due to the biocompatibility and
resistance to corrosion of its thin oxide layer [56]. After implant placement, the bone
surrounding the implant interacts with the stable oxide layer found on the Ti surface and
its alloys. This thin, durable, self-repairing oxide layer plays an important role in the
osseointegration of the implant by mediating cell-surface interactions such as protein ad-
sorption, cell adhesion and differentiation, and eventually bone formation and remodeling.
The present study employed XPS analysis, in order to study modifications in the TiO2
properties. Notably, the element Ti was not detected in any of the samples. This may be
due to the fact that samples were sputtered using a 2kV argon ion gun. The sputtering
rate was 1 angstrom per second for 10 seconds, which allowed for a penetration of ca.
1 nm into the oxide layer. This finding may be explained by the assumption that Ti is
located at a deeper layer and for instance, this may be further investigated by sputtering
the samples for a longer period of time, and this finding warrants further investigation.
However, as previously mentioned by means of EDX analyses, the presence of the element
Ti was confirmed in all the samples, but not its state of oxidation, which may affect the
biocompatibility of the titanium surface [51]. Further investigation is needed in order to
assess the effect that this can cause in the re-osseointegration process.
It has been shown that re-osseointegration of previously contaminated implant sur-
faces is possible, and it is suggested that this mainly depends upon the surface of the im-
plant, the types of decontamination techniques and bone regenerative materials used [57].
It seems that osteoblasts adhere more rapidly to rough surfaces [58]. However, some
authors concluded that attachment is rather influenced by surface chemistry than surface
roughness [59]. The results herein presented concur with this statement, and with previous
studies that found that materials that have a similar roughness—and yet only differ in
surface wettability- those that are super-hydrophilic have superior bioactivity [60,61].
It is important to point out that conflicting evidence has arisen in relation with auto-
claving sterilisation of Ti surfaces. Some studies report no significant modifications of the
oxide layer following autoclaving sterilization [62]. In contrast, other studies have found
that the thickness, oxidation state, and composition vary with the sterilisation process
used [50]. In the present study, an additional group SC (i.e., sterile disc not autoclaved) was
included in the cell proliferation assay in order to compare, if any, significant differences
with the group SA (i.e., sterile disc plus autoclaving). Additionally, in the surface chemistry
analyses the SA group was included, so as to compare the surface chemistry with the
SC group. No significant differences were found between these two groups by EDX and
XPS analyses.
The wettability or surface free energy of a substrate, is thought to play a pivotal role in
the initial events that take place after implantation. In addition, no significant differences
were found in terms of contact angles and Ra values, before and after sterilisation by
autoclaving. However, the state of oxidation of the Ti oxide layer, as previously mentioned,
was not determined and this aspect warrants further investigation. The latter is relevant
given the effect of microbial biofilms have in inducing microenvironments that facilitate
corrosion of Ti surfaces with subsequent release of Ti particles, which may synergise with
tribocorrosion and facilitate implant failure. Host interactions to peri-implantitis biofilms
and decontamination protocols warrants further investigation.
3.2.5. SEM and CLSM Imaging of MG-63
In the present study, autoclaving sterilisation was performed previous to cell culture.
The rationale behind sterilising the Ti surfaces previous to the proliferation assay is essen-
tially due to the Alamar blue fluorescence/absorbance readings that may be influenced by
live bacteria and yield inaccurate measurements. The SEM analyses, performed prior to the
Int. J. Mol. Sci. 2022, 23, 10033 10 of 15
cytocompatibility assay, of treated Ti surfaces were found to harbour bacterial remnants.
In this scenario, live bacterial cells will contribute to the cell number measurement in the
AB assay. As such, live MG-63 and bacterial cells will both reduce resazuring (i.e., blue
non-fluorescent compound) to resorufin (i.e., red fluorescence), thus both sources will
contribute to such cell counts readings. In the present study, cell proliferation may have
been enhanced by UV-C irradiation, time, type of treatment and surface roughness. Even
though the MCA group was completely sterile, the fact that the lowest cell proliferation
yield was found in this group, highlights the importance that the organic remnants left
behind have in reducing the cell proliferation and warrant further investigation. UV-C
photofunctionalised Ti surfaces had higher cells/mL yields. A higher amount of MG-63
cell was found at day 7 in comparison to day 1. Surface roughness seems to play a role only
at day 1, when SLA surfaces had a higher cell/mL yield. Interestingly, at days 4 and 7 M
treated surfaces had a higher cell proliferation than the SLA treated surfaces.
The group T1A+ had the highest amount of cells/mL and there were no significant
differences between T2A+ and T3A+. It is hypothesised that these results were related
mainly to the surface chemistry, since the inorganic remnants of the chemical substances
used for contamination may have caused a delay in the cell proliferation. However, these
elements did not seem to have altered the surface biocompatibility. Bone cells may be
sensitive to the morphology of the material, leading to differences in their shape, orientation
and adhesion [42,55]. However, in the present study, MG-63 cells were able to grow on all
treated surfaces and no morphological differences were observed at day 7 of incubation.
4. Materials and Methods
4.1. Microcosm Biofilm Growth
Biofilms were grown in a Constant Depth Film Fermentor (CDFF) peri-implantitis
biofilm model as previously described [6]. The CDFF was inoculated with 500 mL of
artificial saliva containing 1 mL aliquot of a pooled stock of human whole saliva. Micro-
cosm biofilms were grown over commercially pure Machined (Sa = 0.40 µm) and SLA
(Sa = 1.79 µm) Ti discs (grade IV; ASTM F 67; Institut Straumann AG, Basel, Switzerland)
of 5 mm in diameter and 1 mm of thickness were used. Ethical approval of the protocol for
human whole saliva sample collection and experimental research was provided by UCL
Research Ethics Committee approval (1364/001).
4.2. Microcosm Biofilm Disruption
The different decontamination treatment modalities that were used in test groups
and the positive (MC) and negative (SC, SA) controls are shown in Table 1. The specific
decontamination protocols are summarised below.
4.2.1. T1: Mechanical Disruption with Ti Brush
Mechanical disruption of the biofilms was performed by means of a titanium coated
brush (TiB) (TiBrushTM Straumann; Basel, Switzerland) with a shank of 10mm in length
and a titanium bristle at the end, fitted to a slow speed NSK (Nakanishi Inc., Tochigi, Japan)
contra angle oscillating hand-piece (ER1 6i 16:1). The mechanical decontamination was
carried out at a speed of 900 rpm, for 60 seconds, using a unidirectional movement across
the disc. For each disc, a new TiB was used with a force of 0.3–0.5N. To avoid any contact on
the surface of interest, the Ti disc was inserted into a custom-made disc holder (Staumann,
Basel, Switzerland). This allowed surface decontamination without any interferences from
any instrument. During the use of the TiB, the surface of the disc was simultaneously
irrigated with 0.9% Phys. NaCl. Finally, the discs were rinsed 3 times, by dipping them
into a well-plate containing 0.9% Phys. NaCl.
4.2.2. T2: TiB + Photodynamic Therapy
Photodynamic therapy—PDT (PeriowaveTM, Vancouver, BC, Canada [λ 660–675 nm,
11 mW]), was used following the mechanical treatment of the Ti disc surfaces by the
Int. J. Mol. Sci. 2022, 23, 10033 11 of 15
use of the TiB for 60s (as described above). One mL of photosensitiser (PS) consisted of
3,7-Bis (dymethyl-amino) phenazathionium chloride trihydrate (methylene blue) at the
concentration of 0.005% (w/v) was added to the Ti disc, making sure that the entire surface
was covered and left in situ for 60 s prior to irradiation [63]. This allowed sufficient uptake
of the photosensitiser by the targeted microorganisms, and for the optimal action of the
laser. A uniform light distribution was emitted from the tip of the pulsed diode soft laser
(PeriowaveTM, Vancouver, BC, Canada) at a fixed distance of 10 cm from the disc. Static
irradiation (25 mW/cm2) for the entire disc was completed in 60 s. The methylene blue
was removed by dipping the disc into 0.9% Phys. NaCl (PBS), and repeatedly in a fresh
new 0.9% Phys. NaCl to ensure removal of the photosensitiser until the disc was free of all
visible methylene blue residues.
4.2.3. T3: TiB + Chemical Agents
Chemical decontamination was performed following the mechanical treatment of the
Ti disc surfaces by the use of the TiB for 60 s (as described above). Thereafter 1 mL of 1%
NaOCl was applied for 60 s, after which the Ti disc was dipped in a sterile well-plate with
2 mL of a solution of 0.9% Phys. NaCl, and later in 1mL of 0.2% CHX for 60 s and before
being rinsed.
4.2.4. MC+, SC+, SA+, T1+, T2+, T3+: Ultraviolet Irradiation C
UV-C irradiated discs shown with a + symbol in Table 1 received a source of standard-
ised UV-C light (4.2 mW/cm2, λ 254 nm, 230 V, 50 Hz, ca. 30 ◦C at Ti surfaces) at 10 cm
from the source and centred. The irradiation installation was performed inside an opaque
chamber, in order to prevent interference from the room or daylight, or cause any damage
to users.
4.3. Effect of Therapies on Viable Cell Counts
The biofilm composition and bacterial remnants were investigated in the control
and treatment groups before and after treatment across different decontamination strate-
gies and substrata on SLA and M Ti surfaces with non-selective culture media analyses.
Aerobes were cultured by plating the dilutions onto columbia blood agar (CBA [LabM,
Lancashire, UK]). Anaerobes were isolated on to fastidious anaerobe agar (FAA [LabM,
Lancashire, UK]).
4.4. Effect of Therapies on Surface Topography, Wettability, Chemistry and Biocompatibility
The detailed methodology is included in the supplemental file (Supplementary Materi-
als). In brief, qualitative images were taken before and after treatment (Table 1) employing
Scanning Electron Microscopy (SEM) (JEOL JSM 5410LV, Hertfordshire, UK) (Supplemen-
tary Materials).
Surface topography (Proscan 1000, Scantron Ltd., Somerset, UK [laser KL131A, resolu-
tion {z} 0.02 µm]), and wettability (CAM 200, KSV Instruments, Biolin Scientific, MD, USA)
were assessed (Supplementary Materials).
The effect of the different decontamination protocols on surface chemistry (Ther-
mofisher Scientific K-Alpha XPS system with Avantage software and JEOL JSM-6301F;
Oxford Instruments INCA EDX) were tested (Supplementary Materials).
Biocompatibility (MG-63, European Collection of Cell Cultures, Porton Down, UK),
was evaluated (Supplementary Materials). Following the cytocompatibility assay, SEM and
CLSM images (Bio-Rad Laboratories Ltd, Hemel Hempstead, Hertfordshire, UK) of MG-63
cells were obtained (Supplementary Materials).
4.5. Statistical Analyses
The number of colony forming units per biofilm was determined (i.e., CFU/biofilm =
NCFU × DF × 50—where NCFU is the number of colonies, DF is the dilution factor and 50
is the inverse of volume plated). The means, SE (the SD of a statistic) of means and 95% CI
Int. J. Mol. Sci. 2022, 23, 10033 12 of 15
of log10 CFU/biofilm bacterial counts [64] of the experimental groups (Table 1). Then, the
analysis of residuals was performed and assumptions were satisfied only after the log10
transformation of the count data (CFU/biofilm). Thus, log10 CFU/biofilm was used to
perform parametric statistics. Univariate general linear model (mean predicted values) and
multiple comparisons with Bonferroni post-hoc corrections were performed to compare
the log10 transformed bacterial counts per mL of each sample characteristics (i.e., control
and experimental groups) and by surface characteristics. Then, differences in terms of log10
CFU/biofilm between surfaces were performed first with a two-way univariate analysis
of variance in order to test surface and treatment as main effects and whether interactions
were present.
Linear regression analysis was performed as a first step in order to test whether
a number of variables (day, therapy, UV-C and surface characteristics) were influencing
the cytocompatibility response (i.e., number of cells/mL). Since, these variables resulted
to be influencing the cytotoxicity response, then, a repeated measures ANOVA multilevel
model 4-way interaction was performed in the cell proliferation experiment to compare the
variables across time and at different levels (p < 0.0001).
Descriptive statistics were performed for the changes observed in the surface topogra-
phy, and wettability. Surface chemistry was analysed through SEM/EDX INCA software to
process the acquired data, then means ± SD of atomic percentage (at. %) were compared.
XPS data scans were modeled using CASAXPS software and relevant descriptive graphs
were included.
Qualitative analyses were undertaken for the changes observed in SEM and CLSM
images across surfaces and treatments.
5. Conclusions
The data presented in this in vitro study suggest that titanium surface biocompatibility
to MG-63 cells was not hindered by the use of TiB, combination of TiB and photodynamic
therapy, or combination of TiB and 0.2%CHX/1%NaClO.
It was demonstrated that:
1. Bacterial debris will prevail after mechanical and combination therapy.
2. Photofunctionalisation of the Ti surface with Ultraviolet-C (UV-C) radiation appears
to have a positive effect in the Ti surface biocompatibility. MG-63 cell proliferation was
enhanced by photofunctionalisation of the Ti surface by the use of UV-C irradiation,
time, type of treatment and type of surface. The outcomes of this cytocompatibility
study favours decontamination of smooth surfaces, and photofunctionalisation of the
TiO2 layer.
3. All decontamination protocols induced modifications of the Ti oxide layer surface
properties. Therefore, it is plausible to focus future research on developing decontam-
ination protocols that facilitate the re-establishment of a biocompatible state of the
implant surface chemistry.
4. Successful treatment for peri-implantitis should integrate a comprehensive approach,
including not only the elimination of live bacteria, but also the bacterial debris, and
taking into account the Ti surface biomaterial alterations, re-contamination of implant
surfaces, and host interactions. Therefore, decontamination protocols for titanium (Ti)
surfaces should be carefully chosen by the clinician.
Supplementary Materials: The following supporting information can be downloaded at: https:
//www.mdpi.com/article/10.3390/ijms231710033/s1.
Author Contributions: Conceptualization, V.S., D.S., N.M. and N.D.; methodology, V.S., D.S., I.A.H.,
N.J.W., N.M. and N.D.; software, V.S., N.D., I.A.H. and N.J.W.; validation, V.S., D.S. and N.D.; formal
analysis, V.S., D.S. and N.D.; investigation, V.S., D.S. and N.D.; resources, V.S., D.S. and N.D.; data
curation, V.S., D.S. and N.D.; writing—original draft preparation, V.S.; writing—review and editing,
V.S., D.S., V.B., N.M. and N.D.; visualization, V.S.; supervision, V.S., D.S., N.M. and N.D.; project
Int. J. Mol. Sci. 2022, 23, 10033 13 of 15
administration, V.S., D.S. and N.D.; funding acquisition, V.S., D.S. and N.D. All authors have read
and agreed to the published version of the manuscript.
Funding: Authors V.S., D.S., N.M., N.D. had support from the UCLH/UCL Biomedical Research
Centre for this work and the study took place at University College London (UCL), Eastman Dental
Institute and Hospital, and Eastman Clinical Investigation Centre. V.S. was supported by National
Institute for Health Research, and by University College London.
Institutional Review Board Statement: The research described here was conducted ethically in
accordance with the World Medical Association Declaration of Helsinki. This study was approved
by UCL Research Ethics Committee approval (1364/001) and all volunteers provided written in-
formed consent.
Informed Consent Statement: Informed consent was obtained from all participants involved in
the study.
Data Availability Statement: The datasets used and analysed in this study are available from the
corresponding author upon request.
Acknowledgments: This research benefited from multiple discussions with several researchers and
we are grateful to David Boniface and Aviva Petrie from UCL Eastman Dental Institute Biostatistics,
UCL Institute of Child Health, Genomics Department, UCL Bioscience Division, Clinical Research,
Biomaterials and Tissue Engineering, and Microbial Diseases Departments at the EDI; UCL Chemistry
Department. We acknowledge support from the National Council for Science and Technology
and from Institut Straumann AG, Basel, Switzerland, in the form of the provision of Ti discs and
CDFF bioreactor.
Conflicts of Interest: The authors declare no conflict of interest.
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