锌和氮改性二氧化钛纳米粒子/介孔三氧化二铝复合树脂的制备及其性能评价

doi:10.13481/j.1671-587X.20250406

Abstract

Abstract:

? Objective To prepare novel dental composite resins using zinc（Zn）- and nitrogen（N）- modified titanium dioxide （TiO?） nanoparticles （NPs） and mesoporous alumina （Al?O?，r type， 20 mm） NPs as reinforcing fillers， systematically evaluating their antibacterial activity， mechanical strength， basic performance， and biosafety to obtain the dental composite resins with excellent antibacterial activity and mechanical strength. Methods Zn-N-TiO? NPs and mesoporous Al?O? NPs were added into a resin matrix at varying mass ratios to prepare five composite resins： control group （no filler）， group 0 （Zn-N-TiO?∶Al?O?=1∶0）， group 1 （Zn-N-TiO?∶Al?O? = 1∶1）， group 2 （Zn-N-TiO?∶Al?O?=1∶2）， and group 3 （Zn-N-TiO?∶Al?O?=1∶3）. Plate colony counting method was used to detect the number of adhered bacteria on composite resin surfaces in various groups and calculate the antibacterial rate； scanning electron microscope （SEM） was used to observe the morphology of adhered bacteria in various groups； universal testing machine was used to measure flexural strength （FS） and elastic modulus （EM） of composite resins in various groups； SEM was used to observe fracture surface morphology of composite resins in various groups； microhardness tester was used to determine Vickers microhardness of the composite resins in various groups； Fourier transform infrared spectroscope was used to detect double bond conversion rate （DC） after 20 s photocuring and calculate curing depth； water contact angle meter was used to measure water contact angle （WCA）， water sorption property （WSP）， and water solubility level （WSL） of composite resins in various groups； cell counting kit-8 （CCK-8） method was used to evaluate relative growth rate （RGR） of the mouse fibroblast L-929 cells cultured in composite resin extracts on days 1， 3， and 5 and determine in vitro cytotoxicity grade. Results The plate colony counting results showed that compared with control group， the colony counts on agar plates in the other groups were significantly reduced， with group 1 showing the lowest count. The SEM images results showed densely distributed and morphologically intact Streptococcus mutans in control group； small clusters of bacteria with depressed cell membranes in group 0 and group 3； sparsely distributed bacteria with obvious membrane shrinkage and cytoplasmic leakage in group 1 and group 2. No statistically significant difference in colony counts was found between group 1 and group 2 （P>0.05）， but both were lower than the other groups （P<0.05）. All the composite resins in experimental groups exhibited >85% antibacterial rates， with group 1 and group 2 exceeding 99%.The composite resins in group 0 showed the lowest FS. With addition of mesoporous Al?O?， the FS of the composite resin in group 1 and group 2 were significantly increased， with the composite resin in group 2 showing the highest FS among all groups. Although the FS of the composite resin in group 3 was lower than that in group 2， but it remained higher than other groups （P<0.05）. The SEM images results showed that in control group， the smooth-surfaced sillicon dioxide （SiO?） particles exhibited clear fracture interfaces with resin matrix， with >50% particle exposure； the composite resin in group 0 showed similar morphology and large Zn-N-TiO? agglomerates with tight filler-matrix bonding； the composite resin in group 1， 2， and 3 showed resin adhesion to SiO? surfaces （<50% particle exposure） and uneven fracture surfaces. Fractured SiO? spheres were observed in group 2. Filler distribution was uniform in group 1 and group 2， while the minor NP agglomeration occurred in group 3. The composite resin in control group showed the lowest EM. The EM was significantly improved in experimental groups， with group 3 having the highest value. Group 0 exhibited the lowest Vickers microhardness， showing statistically significant differences among other groups （P<0.05）. The Vickers microhardness of the composite resion was gradually increased with the rising of Al?O? content.The resins in group 2 and group 3 achieved >45 HV hardness， representing increases of 29.73% and 33.82% compared with control group， and 51.34% and 56.28% compared with group 0. No significant differences in DC of the composite resin were found among groups （P>0.05）. The depth of cure for all composite resin groups exceeded 4 mm， with no significance differences observed between various groups （P>0.05）. The composite resin in group 0 showed the smallest WCA. The hydrophobicity of the composite resion was increased with the rising of Al?O? content， but all the WCA values remained <80°. The composite resin in group 3 had the largest WCA without statistical significance compared with group 2 （P>0.05）. Filler incorporation reduced the water sorption/solubility. The composite resin in the CCK-8 assay results showed the composite resins in all groups had RGR>75%， meeting in vitro safety standards. Conclusion Reinforcing fillers impart superior antibacterial activity and mechanical properties to composite resins. Under experimental conditions， group 2 composite resin achieves optimal comprehensive performance in antibacterial efficacy and mechanical strength， demonstrating promising clinical application potential.

Key words: ? Composite resin, Titanium dioxide, Mesoporous alumina, Antibacterial property, Mechanical strength

CLC Number:

R783.1

Rong HAN,Zhimin ZHANG,Yuanhang ZHAO,Jiayi WANG,Wenjun TANG,Hong ZHANG. Preparation of zinc and nitrogen modified titanium dioxide nanoparticles/mesoporous alumina composite resin and its performance evaluation[J].Journal of Jilin University(Medicine Edition), 2025, 51(4): 904-913.

Figures/Tables 8

Tab.1

Tab. 2

Fig. 1

Tab. 3

Tab.4

Fig. 2

Tab. 5

Tab.6

References 30

[1]	OPDAM N M， VAN DE SANDE F H， BRONKHORST E， et al. Longevity of posterior composite restorations： a systematic review and meta-analysis［J］. J Dent Res， 2014， 93（10）： 943-949.
[2]	MELO M S， GARCIA I M， MOKEEM L， et al. Developing bioactive dental resins for restorative dentistry［J］. J Dent Res， 2023， 102（11）： 1180-1190.
[3]	MANSOOR A， KHURSHID Z， KHAN M T， et al. Medical and dental applications of titania nanoparticles： an overview［J］. Nanomaterials （Basel）， 2022， 12（20）： 3670.
[4]	RASHID R， SHAFIQ I， GILANI M R H S， et al. Advancements in TiO₂-based photocatalysis for environmental remediation： strategies for enhancing visible-light-driven activity［J］. Chemosphere， 2024， 349： 140703.
[5]	ZHAO Y H， ZHANG H， HONG L H， et al. A multifunctional dental resin composite with Sr-N-doped TiO₂ and n-HA fillers for antibacterial and mineralization effects［J］. Int J Mol Sci， 2023， 24（2）： 1274.
[6]	SUIB S L. A review of recent developments of mesoporous materials［J］. Chem Rec， 2017， 17（12）： 1169-1183.
[7]	ZHANG S N， WANG X， YANG J W， et al. Micromechanical interlocking structure at the filler/resin interface for dental composites： a review［J］. Int J Oral Sci， 2023， 15（1）： 21.
[8]	KUEMMEL M， GROSSO D， BOISSIÈRE C， et al. Thermally stable nanocrystalline gamma-alumina layers with highly ordered 3D mesoporosity［J］. Angew Chem Int Ed， 2005， 44（29）： 4589-4592.
[9]	YUAN Q， YIN A X， LUO C， et al. Facile synthesis for ordered mesoporous gamma-aluminas with high thermal stability［J］. J Am Chem Soc， 2008， 130（11）： 3465-3472.
[10]	ZIENTAL D， CZARCZYNSKA-GOSLINSKA B， MLYNARCZYK D T， et al. Titanium dioxide nanoparticles： prospects and applications in medicine［J］. Nanomaterials （Basel）， 2020， 10（2）： 387.
[11]	ESTRIN Y， KRISHNAMURTHY V R， AKLEMAN E. Design of architectured materials based on topological and geometrical interlocking［J］. J Mater Res Technol， 2021， 15： 1165-1178.
[12]	JENIMA J， PRIYA DHARSHINI M， AJIN M L， et al. A comprehensive review of titanium dioxide nanoparticles in cementitious composites［J］. Heliyon， 2024， 10（20）： e39238.
[13]	CHEN H Y， WANG R L， QIAN L， et al. Dental restorative resin composites： modification technologies for the matrix/filler interface［J］. Macro Materials & Eng， 2018， 303（10）： 1800264.
[14]	RASTELLI A N S， JACOMASSI D P， FALONI A P S， et al. The filler content of the dental composite resins and their influence on different properties［J］. Microsc Res Tech， 2012， 75（6）： 758-765.
[15]	FERRACANE J L. Hygroscopic and hydrolytic effects in dental polymer networks［J］. Dent Mater， 2006， 22（3）： 211-222.
[16]	ALSHALI R Z， SALIM N A， SATTERTHWAITE J D， et al. Long-term sorption and solubility of bulk-fill and conventional resin-composites in water and artificial saliva［J］. J Dent， 2015， 43（12）： 1511-1518.
[17]	FINER Y， SANTERRE J P. The influence of resin chemistry on a dental composite’s biodegradation［J］. J Biomed Mater Res A， 2004， 69（2）： 233-246.
[18]	SUN J R， PETERSEN E J， WATSON S S， et al. Biophysical characterization of functionalized titania nanoparticles and their application in dental adhesives［J］. Acta Biomater， 2017， 53： 585-597.
[19]	DONG C， NI X Y. The photopolymerization and characterization of methyl methacrylate initiated by nanosized titanium dioxide ［J］. J Macromolecul Science-Pure App Chem， 2004， A41（5）： 547-63.
[20]	VOUVOUDI E C. Overviews on the progress of flowable dental polymeric composites： their composition， polymerization process， flowability and radiopacity aspects［J］. Polymers， 2022， 14（19）.
[21]	DONG C， NI X Y. The photopolymerization and characterization of methyl methacrylate initiated by nanosized titanium dioxide［J］. J Macromol Sci Part A， 2004， 41（5）： 547-563.
[22]	YIN X， LUO Y J. The optical shielding performances and mechanisms of green flame-retardant two-component matte films under various application conditions［J］. RSC Adv， 2021， 11（21）： 12696-12702.
[23]	VOGLER E A. Structure and reactivity of water at biomaterial surfaces［J］. Adv Colloid Interface Sci， 1998， 74： 69-117.
[24]	TOPCU F T， SAHINKESEN G， YAMANEL K， et al. Influence of different drinks on the colour stability of dental resin composites［J］. Eur J Dent， 2009， 3（1）： 50-56.
[25]	JAFFER F， FINER Y， SANTERRE J P. Interactions between resin monomers and commercial composite resins with human saliva derived esterases［J］. Biomaterials， 2002， 23（7）： 1707-1719.
[26]	TEUGHELS W， VAN ASSCHE N， SLIEPEN I， et al. Effect of material characteristics and/or surface topography on biofilm development［J］. Clin Oral Implants Res， 2006， 17（）： 68-81.
[27]	SPENCER P， YE Q， PARK J， et al. Adhesive/Dentin interface： the weak link in the composite restoration［J］. Ann Biomed Eng， 2010， 38（6）： 1989-2003.
[28]	SON Y， LEE M K， PARK Y C. Contact angle relaxation on amorphous， mixed-phase （anatase+ rutile）， and anatase TiO₂ films and its mechanism［J］. Langmuir， 2021， 37（5）： 1850-1860.
[29]	VAN LANDUYT K L， NAWROT T， GEEBELEN B， et al. How much do resin-based dental materials release？ A meta-analytical approach［J］. Dent Mater， 2011， 27（8）： 723-747.
[30]	YANG S S， LIAN G J. ROS and diseases： role in metabolism and energy supply［J］. Mol Cell Biochem， 2020， 467（1/2）： 1-12.

Group	Mass ratio
Group	Zn-N-TiO₂	Al₂O₃	SiO₂	Resin matrix
Control	0	0	60	40
Group 0	6.0	0	54	40
Group 1	3.0	3.0	54	40
Group 2	2.0	4.0	54	40
Group 3	1.5	4.5	54	40

Toxicity grading	RGR	Safety evaluation
Grade 1	≥100%	Safe
Grade 2	75%-99%	Safe
Grade 3	50%-74%	Unsafe
Grade 4	25%-49%	Unsafe
Grade 5	1%-24%	Unsafe
Grade 6	<1%	Unsafe

Group	Colony count（×10⁶ CFU·mL^-1）	Antimicrobial rate（η/%）
Control	83.83±5.38	—
Group 0	10.77±1.04^*	87.16±1.24
Group 1	1.20±0.36^*△	98.57±0.43^△
Group 2	3.03±0.85^*△	96.38±1.01^△
Group 3	8.30±1.15^*	90.10±1.37^△

Group	FS （P/MPa）	EM（P/GPa）	Vickers microhardness (HV)
Control	93.07±4.01	2.24±0.14	35.28±1.81
Group 0	80.89±8.03^*	2.80±0.11^*	30.21±1.29^*
Group 1	112.26±5.08^*△	3.27±0.11^*△	39.41±1.28^*△
Group 2	129.84±4.52^*△	3.57±0.13^*△	45.77±0.57^*△
Group 3	123.83±7.37^*△	3.72±0.11^*△	47.21±0.98^*△

Group	DC（η/%）	Curing depth（l/mm）	WCA (θ/°)	WSP (μg·mm^-3)	WSL (μg·mm^-3)
Control	48.66±1.02	4.98±0.14	66.73±1.41	30.30±0.78	0.68±0.09
Group 0	47.52±1.14	4.30±0.23^*	65.06±1.28^*	25.22±0.88^*	0.70±0.06
Group 1	49.66±0.73	4.41±0.03^*	70.51±1.55^*△	17.31±0.74^*△	0.28±0.06^*△
Group 2	48.89±0.89	4.51±0.18^*	75.34±1.80^*△	15.03±0.48^*△	0.16±0.04^*△
Group 3	48.62±1.12	4.54±0.09^*	75.81±1.30^*△	17.09±0.82^*△	0.29±0.05^*△

Preparation of zinc and nitrogen modified titanium dioxide nanoparticles/mesoporous alumina composite resin and its performance evaluation

RichHTML

PDF (PC)

Like

Knowledge

Abstract

Cite this article

share this article

Figures/Tables 8

References 30

Related Articles 5

Metrics

Comments

Recommended 0

Group	RGR （η/%）			Safety evaluation
Group	（t/d） 1	3	5	1	3	5
Control	88.57±1.91	89.44±4.94	88.64±4.94	Safe	Safe	Safe
Group 0	81.75±1.47	86.32±2.40	82.19±3.87	Safe	Safe	Safe
Group 1	90.35±1.90	95.64±4.72	92.46±5.95	Safe	Safe	Safe
Group 2	93.98±1.77	97.94±4.21	95.44±4.67	Safe	Safe	Safe
Group 3	94.00±2.14	98.03±1.89	96.39±6.95	Safe	Safe	Safe

[1]	Kongzhao JIANG,Chiyu LI,Yungang LUO,Zhihui LIU. Preparationof GelMA hydrogel loaded with ZIF-8 and evaluation of drug sustained release and antibacterial effect [J]. Journal of Jilin University(Medicine Edition), 2024, 50(1): 106-112.
[2]	Yuanhang ZHAO,Linlin YAN,Jiazhuo SONG,Xinying ZOU,Hong ZHAO,Xin LIU,Jiawen CHEN,Yiyan YU,Zhimin ZHANG,Hong ZHANG. Preparation and properties of strontium and nitrogen co-doped titanium dioxide/nano hydroxyapatite composites resins [J]. Journal of Jilin University(Medicine Edition), 2023, 49(4): 1067-1075.
[3]	Linlin YAN,Lin ZHU,Yuanhang ZHAO,Jiazhuo SONG,Xinying ZOU,Xin LIU,Hong ZHAO,Zhimin ZHANG,Hong ZHANG. Inhibitory effect of Streptococcus mutans by titanium dioxide nanoparticles combined with LED light irradiation and its mechanism [J]. Journal of Jilin University(Medicine Edition), 2022, 48(4): 929-937.
[4]	Han WANG,Zilu TIAN,Xuanyan ZHU,Yubin YANG,Song ZHU. Preparation of cinnamaldehyde antibacterial adhesive and evaluation on its antibacterial property [J]. Journal of Jilin University(Medicine Edition), 2021, 47(5): 1116-1123.
[5]	JIANG Wei, YANG Luyi, ZHU Huifang, DONG Yan, MOU Yinhe, WU Yanran, NING Lei. Effect of methacrylic acid coupled TiO₂ on machanical properties of self-curing denture [J]. Journal of Jilin University Medicine Edition, 2015, 41(05): 946-950.