[1] Tjäderhane L. Dentin bonding:Can we make it last?[J]. Oper Dent, 2015, 40(1):4-18. [2] Tjäderhane L, Nascimento FD, Breschi L, et al. Strategies to prevent hydrolytic degradation of the hybrid layer-A review[J]. Dent Mater, 2013, 29(10):999-1011. [3] Yi L, Yu J, Han L,et al. Combination of baicalein and ethanol-wet-bonding improves dentin bonding durability[J]. J Dent, 2019, 90:103207. [4] Simmer FS, da Silva EM,Bezerra RDSG, et al. Bond stability of conventional adhesive system with MMP inhibitors to superficial and deep dentin[J]. J Mech Behav Biomed Mater, 2019, 100:103402. [5] WangJJ, Dou XJ, Song J, et al. Antimicrobial peptides:Promising alternatives in the post feeding antibiotic era[J]. Med Res Rev, 2019, 39(3):831-859. [6] Marsh PD. Controlling the oral biofilm with antimicrobials[J]. J Dent, 2010,38(Suppl 1):S11-S15. [7] Chen C, Cheng L, Weir MD,et al. Primer containing dimethylaminododecyl methacrylate kills bacteria impregnated in human dentin blocks[J]. Int J Oral Sci, 2016, 8(4):239-245. [8] Paula AB, Alonso RCB,Taparelli JR, et al. Influence of the incorporation of triclosan methacrylate on the physical properties and antibacterial activity of resin composite[J]. J Appl Oral Sci, 2019, 27:e20180262. DOI:10.1590/1678-7757-2018-0262. [9] Marsh PD, Head DA, Devine DA. Ecological approaches to oral biofilms:Control without killing[J]. Caries Res, 2015, 49(Suppl 1):46-54. [10] Sullivan R,Santarpia P, Lavender S, et al. Clinical efficacy of a specifically targeted antimicrobial peptide mouth rinse:Targeted elimination of Streptococcus mutans and prevention of demineralization[J]. Caries Res, 2011, 45(5):415-428. [11] Melo MN,Ferre R, Castanho MA. Antimicrobial peptides:Linking partition, activity and high membrane-bound concentrations[J]. Nat Rev Microbiol, 2009, 7(3):245-250. [12] Boparai JK, Sharma PK. Minireview on antimicrobial peptides, sources, mechanism and recent applications[J]. Protein Pept Lett, 2020, 27(1):4-16. [13] Epand RM, Walker C, Epand RF, et al. Molecular mechanisms of membrane targeting antibiotics[J]. Biochim Biophys Acta, 2016, 1858(5):980-987. [14] Andersson DI, Hughes D,Kubicek-Sutherland JZ. Mechanisms and consequences of bacterial resistance to antimicrobial peptides[J]. Drug Resist Updat, 2016, 26:43-57. [15] Nguyen LT, Haney EF, Vogel HJ. The expanding scope of antimicrobial peptide structures and their modes of action[J]. TrendsBiotechnol, 2011, 29(9):464-472. [16] Kreling PF, Aida KL, Massunari L, et al. Cytotoxicity and the effect of cationic peptide fragments against cariogenic bacteria under planktonic and biofilm conditions[J]. Biofouling, 2016, 32(9):995-1006. [17] Kõll-Klais P, Mändar R, Leibur E, et al. Oral lactobacilli in chronic periodontitis and periodontal health:Species composition and antimicrobial activity[J]. Oral Microbiol Immunol, 2005, 20(6):354-361. [18] Liang DS, Li HY, Xu XH, et al. Rational design of peptides with enhanced antimicrobial and anti-biofilm activities against cariogenic bacterium Streptococcus mutans[J]. Chem Biol Drug Des, 2019, 94(4):1768-1781. [19] Liang JH, Liang DS, Liang YE, et al. Effects of a derivative of reutericin 6 and gassericin A on the biofilm of Streptococcus mutans in vitro and caries prevention in vivo[J]. Odontology, 2021, 109(1):53-66. [20] Deslouches B, Phadke SM, Lazarevic V, et al. De novo generation of cationic antimicrobial peptides:Influence of length and tryptophan substitution on antimicrobial activity[J]. Antimicrob Agents Chemother, 2005, 49(1):316-322. [21] Kaplan CW, Sim JH, Shah KR,et al. Selective membrane disruption:Mode of action of C16G2, a specifically targeted antimicrobial peptide[J]. Antimicrob Agents Chemother, 2011, 55(7):3446-3452. [22] Jiang WT, Wang YF, Luo JY, et al. Antimicrobial peptide GH12 prevents dental caries by regulating dental plaque microbiota[J]. Appl Environ Microbiol, 2020, 86(14):e00527-e00520. [23] Li L, He J, Eckert R, et al. Design and characterization of an acid-activated antimicrobial peptide[J]. Chem Biol Drug Des, 2010, 75(1):127-132. [24] Jiang W, Luo J, Wang Y, et al. The pH-responsive property of antimicrobial peptide GH12 enhances its anticaries effects at acidic pH[J]. Caries Res, 2021, 55(1):21-31. [25] Kashiwada A, Mizuno M, Hashimoto J. pH-Dependent membrane Lysis by using melittin-inspired designed peptides[J]. Org Biomol Chem, 2016, 14(26):6281-6288. [26] Wang Y, Fan Y, Zhou Z, et al. De novo synthetic short antimicrobial peptides against cariogenic bacteria[J]. Arch Oral Biol, 2017, 80:41-50. [27] Jiang WT, Wang YF, Luo JY, et al. Effects of antimicrobial peptide GH12 on the cariogenic properties and composition of a cariogenic multispecies biofilm[J]. Appl Environ Microbiol, 2018, 84(24):e01423-e01418. [28] Xie SX, Song L, Yuca E, et al. Antimicrobial peptide-polymer conjugates for dentistry[J]. ACS Appl Polym Mater, 2020, 2(3):1134-1144. [29] Xie SX, Boone K, VanOosten SK, et al. Peptide mediated antimicrobial dental adhesive system[J]. Appl Sci (Basel), 2019, 9(3):557. [30] Wisdom C, VanOosten SK, Boone KW, et al. Controlling the biomimetic implant interface:Modulating antimicrobial activity by spacer design[J]. J Mol Eng Mater, 2016, 4(1):1640005. [31] Wisdom EC, Zhou Y, Chen C, et al. Mitigation of peri-implantitis by rational design of bifunctional peptides with antimicrobial properties[J]. ACS Biomater Sci Eng, 2020, 6(5):2682-2695. [32] Song LY, Ge XP, Ye Q, et al. Modulating pH through lysine integrated dental adhesives[J]. Dent Mater, 2018, 34(11):1652-1660. [33] Yi X, He JP, Wang XL, et al. Tunable mechanical, antibacteri-al, and cytocompatible hydrogels based on a functionalized dual network of metal coordination bonds and covalent crosslinking[J]. ACS Appl Mater Interfaces, 2018, 10(7):6190-6198. [34] Tong ZC, Dong LP, Zhou L, et al. Nisin inhibits dental caries-associated microorganism in vitro[J]. Peptides, 2010, 31(11):2003-2008. [35] Cerrutti P, Terebiznik MR, de Huergo MS, et al. Combined effect of water activity and pH on the inhibition of Escherichia coli by nisin[J]. J Food Prot, 2001, 64(10):1510-1514. [36] Su MX, Yao SY, Gu LS, et al. Antibacterial effect and bond strength of a modified dental adhesive containing the peptide nisin[J]. Peptides, 2018, 99:189-194. [37] Zhao M, Qu Y, Liu J, et al. A universal adhesive incorporating antimicrobial peptide nisin:effects on Streptococcus mutans and saliva-derived multispecies biofilms[J].Odontology, 2020,108(3):376-385. [38] Ye Q, Spencer P, Yuca E, et al. Engineered peptide repairs defective adhesive-dentin interface[J].Macromol Mater Eng,2017,302(5):1600487. [39] Zhou C, Zhang D, Bai Y, et al. Casein phosphopeptide-amorphous calcium phosphate remineralization of primary teeth early enamel lesions[J].J Dent,2014,42(1):21-29. [40] Chen F, Jia ZS, Rice KC, et al. The development of dentotropic micelles with biodegradable tooth-binding moieties[J]. Pharm Res, 2013, 30(11):2808-2817. [41] Zhou L, Wong HM, Zhang YY, et al. Constructing an antibiofouling and mineralizing bioactive tooth surface to protect against decay and promote self-healing[J]. ACS Appl Mater Interfaces, 2020, 12(2):3021-3031. [42] Sarikaya R, Song LY, Yuca E, et al. Bioinspired multifunctional adhesive system for next generation bio-additively designed dental restorations[J]. J Mech Behav Biomed Mater, 2021, 113:104135. [43] Song LY, Ye Q, Ge XP, et al. Self-strengthening hybrid dental adhesive via visible-light irradiation triple polymerization[J]. RSC Adv, 2016, 6(57):52434-52447. [44] Ciumac D, Gong HN, Hu XZ, et al. Membrane targeting cationic antimicrobial peptides[J]. J Colloid Interface Sci, 2019, 537:163-185. |