lactic acid has been researched along with Caries, Dental in 147 studies
Lactic Acid: A normal intermediate in the fermentation (oxidation, metabolism) of sugar. The concentrated form is used internally to prevent gastrointestinal fermentation. (From Stedman, 26th ed)
2-hydroxypropanoic acid : A 2-hydroxy monocarboxylic acid that is propanoic acid in which one of the alpha-hydrogens is replaced by a hydroxy group.
Excerpt | Relevance | Reference |
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"To evaluate the effects of 8% arginine-containing toothpaste on the dental plaque of no caries (NC) and high caries (HC) individuals in situ." | 9.24 | Effect of toothpaste containing arginine on dental plaque-A randomized controlled in situ study. ( Cheng, L; Lu, Q; Ren, B; Tian, Y; Xue, Y; Zhou, X, 2017) |
"Because caries activity may be related to dental plaque acidogenicity, a method was developed for chairside evaluation of pH-lowering activity and lactic acid production by dental plaque." | 7.74 | Chairside evaluation of pH-lowering activity and lactic acid production of dental plaque: correlation with caries experience and incidence in preschool children. ( Igarashi, K; Shimizu, K; Takahashi, N, 2008) |
"Lactic acid was determined enzymatically in glucose-challenged plaque suspensions." | 6.71 | Effect of xylitol-containing chewing gums on lactic acid production in dental plaque from caries active pre-school children. ( Stecksén-Blicks, C; Twetman, S, 2003) |
"To evaluate the effects of 8% arginine-containing toothpaste on the dental plaque of no caries (NC) and high caries (HC) individuals in situ." | 5.24 | Effect of toothpaste containing arginine on dental plaque-A randomized controlled in situ study. ( Cheng, L; Lu, Q; Ren, B; Tian, Y; Xue, Y; Zhou, X, 2017) |
"To our knowledge, there is a lack of evidence on the effect of Antimicrobial Photodynamic Therapy (aPDT) by the application of curcumin against complex biofilms of dental caries lesions." | 3.88 | Curcumin-mediated antimicrobial photodynamic therapy reduces the viability and vitality of infected dentin caries microcosms. ( Afonso Rabelo Buzalaf, M; Andrade Moreira Machado, MA; Cardoso Oliveira, R; Cruvinel, T; Cusicanqui Méndez, DA; Gutierres, E; José Dionisio, E, 2018) |
"Because caries activity may be related to dental plaque acidogenicity, a method was developed for chairside evaluation of pH-lowering activity and lactic acid production by dental plaque." | 3.74 | Chairside evaluation of pH-lowering activity and lactic acid production of dental plaque: correlation with caries experience and incidence in preschool children. ( Igarashi, K; Shimizu, K; Takahashi, N, 2008) |
"This study tests the hypothesis that caries activity is associated with lower degrees of saturation with respect to enamel mineral in dental plaque fluid following sucrose exposure." | 3.71 | Association of caries activity with the composition of dental plaque fluid. ( Fan, Y; Gao, XJ; Kent, RL; Margolis, HC; Van Houte, J, 2001) |
"Samples of whole-mouth saliva and dental plaque were collected from initially 7- to 8-year-old subjects who participated in a 3-year school-based programme investigating the effect of the consumption of polyol-containing candies on caries rates." | 2.78 | Effect of three-year consumption of erythritol, xylitol and sorbitol candies on various plaque and salivary caries-related variables. ( Honkala, E; Honkala, S; Mäkinen, KK; Mäkinen, PL; Nõmmela, R; Olak, J; Runnel, R; Saag, M; Vahlberg, T, 2013) |
"Lactic acid was determined enzymatically in glucose-challenged plaque suspensions." | 2.71 | Effect of xylitol-containing chewing gums on lactic acid production in dental plaque from caries active pre-school children. ( Stecksén-Blicks, C; Twetman, S, 2003) |
"Artificially induced carious lesions on either side of in vitro un/restored amalgam cavities were examined to establish the degree of randomness of caries development." | 2.69 | Histological features of artificial secondary caries adjacent to amalgam restorations. ( Grossman, ES; Matejka, JM, 1999) |
"Lactic acid has a pK of 3." | 2.38 | Microbial aspects of frequent intake of products with high sugar concentrations. ( Carlsson, J, 1989) |
"Honokiol has an inhibitory effect on S." | 1.91 | A Chinese herb preparation, honokiol, inhibits Streptococcus mutans biofilm formation. ( Deng, Y; Hu, T; Lei, L; Ren, S; Xia, M; Yang, Y; Zuo, Y, 2023) |
"The increase in root caries is a serious problem as society ages." | 1.72 | Demonstration of an optical dentin hardness measuring device using bovine dentin with different demineralization times. ( Awazu, K; Hazama, H; Kondo, S; Mine, A; Okumura, S; Tanimoto, H; Tomioka, Y; Yamaguchi, S; Yamamoto, K; Yasuo, K; Yoshikawa, K, 2022) |
"A rat caries model was built, and rat dental plaque was sampled and cultivated on bovine enamel slabs in vitro and subjected to short-term treatment (5 min, 3 times/day)." | 1.72 | Combined Treatment with Fluoride and Antimicrobial Peptide GH12 Efficiently Controls Caries in vitro and in vivo. ( Feng, Z; Han, S; Jiang, X; Li, Z; Takahashi, N; Wang, Y; Washio, J; Zeng, Y; Zhang, L, 2022) |
"Recurrent dental caries is a common cause of failure of tooth-colored restorations." | 1.43 | Designing Multiagent Dental Materials for Enhanced Resistance to Biofilm Damage at the Bonded Interface. ( Arola, DD; Melo, MA; Orrego, S; Weir, MD; Xu, HH, 2016) |
"Results showed that a dental plaque microcosm biofilm model with human saliva as inoculum was formed." | 1.42 | [Dental plaque microcosm biofilm behavior on a resin composite incorporated with nano-antibacterial inorganic filler containing long-chain alkyl quaternary ammonium salt]. ( Chuanjian, Z; Jianhua, G; Junling, W; Qiang, Z; Ruinan, S; Ting, Z, 2015) |
"Early detection of dental caries is vital if improved patient outcomes are to be achieved by reversal of the demineralization process." | 1.39 | Characterizing and identifying incipient carious lesions in dental enamel using micro-Raman spectroscopy. ( Dadlani, D; Mahoney, D; Mann, AB; Mohanty, B, 2013) |
"The present mechanistic in vitro study aimed to investigate dose-response effects of zinc and fluoride on caries lesion remineralization and subsequent protection from demineralization." | 1.38 | Dose-response effects of zinc and fluoride on caries lesion remineralization. ( Lippert, F, 2012) |
"Early dental caries lesions were formed by treating bovine enamel samples for 48 hours at 37 degrees C with a demineralization solution (pH 5." | 1.38 | Effect of bamboo salt-NaF dentifrice on enamel remineralization. ( Choi, CH; Ha, MO; Hong, SJ; Iijima, Y; Jeong, SS; Sohn, W; Youn, HJ, 2012) |
"Artificial carious lesions were created in 2 acid-gel demineralising systems (initially infinitely undersaturated and partially saturated with respect to enamel) giving lesions with different mineral distribution characteristics (high and low R values, respectively) but similar integrated mineral loss values." | 1.37 | Effects of zinc and fluoride on the remineralisation of artificial carious lesions under simulated plaque fluid conditions. ( Badrock, TC; Butler, A; Churchley, D; Cooper, L; Higham, SM; Kearns, S; Lynch, RJ; Thomas, GV, 2011) |
"Five LB species were identified from carious dentine: L." | 1.36 | Diversity of Lactobacillus species in deep carious lesions of primary molars. ( Callaway, A; Kneist, S; Rupf, S; Schmidt, F; Thiede, B; Wicht, M; Willershausen, B, 2010) |
"Three measurements of carious dentin depth were made in each specimen by CLSM." | 1.35 | Confocal laser scanning microscopic analysis of the depth of dentin caries-like lesions in primary and permanent teeth. ( Correr-Sobrinho, L; de Carvalho, FG; de Fucio, SB; Puppin-Rontani, RM; Sinhoreti, MA, 2008) |
"Data collection included number of carious lesions (D-T) and filled teeth (F-T), approximal plaque index (API), LAP, buffering capacity (BC), counts of mutans streptococci (MS) and lactobacilli (LB) in stimulated saliva." | 1.35 | Comparison of a new chairside test for caries risk assessment with established methods in children. ( Azrak, B; Callaway, A; Ebadi, S; Gleissner, C; Willershausen, B, 2008) |
"Examiners conducted dental caries clinical examination using established criteria." | 1.34 | Microbial acid production (Clinpro Cario L-Pop) and dental caries in infants and children. ( Bretz, WA; Corby, PM; Costa, S; Filho, MR; Moreira, G; Quadros, M; Tavares, VS; Weyant, RJ, 2007) |
"Intranasally administered dental caries vaccines show significant promise for human application." | 1.32 | Remote glucosyltransferase-microparticle vaccine delivery induces protective immunity in the oral cavity. ( Barnes, LA; King, WF; Lam, A; Peacock, Z; Smith, DJ; Taubman, MA; Trantolo, DJ; Wise, DL, 2003) |
"were isolated from dental plaque of all the children." | 1.31 | [Relationship between Streptococcus mutans, Lactobacillus spp. and lactate-producing level and nursing bottle caries]. ( Li, C; Qian, H; Yue, J, 2001) |
"Trehalose was not utilized as a substrate for GTase." | 1.31 | Low-cariogenicity of trehalose as a substrate. ( Hirasawa, M; Neta, T; Takada, K, 2000) |
"Short-chain organic acids of dental plaque from individual subjects were analyzed by capillary electrophoresis." | 1.30 | [Study of acidogenesis of dental plaque on cariogenesis using capillary electrophoresis]. ( Gao, X; Wang, L; Yue, L, 1998) |
"The pH of carious dentin was distinctly lower than that of sound dentin (p < 0." | 1.29 | Acid profiles and pH of carious dentin in active and arrested lesions. ( Hojo, S; Komatsu, M; Okuda, R; Takahashi, N; Yamada, T, 1994) |
"mutans in dental plaque at any time, and is not important in determining the acidogenicity or aciduricity of this organism." | 1.29 | Inhibition of acid production in Streptococcus mutans R9 by formic acid. ( Assinder, SJ; Popiel, HA, 1996) |
"Lactic acid was found in lower concentrations in Fe, Cu, Cu + F, Cu + Fe and F + Fe groups than in the other groups." | 1.29 | Effects of copper, iron and fluoride co-crystallized with sugar on caries development and acid formation in deslivated rats. ( Bowen, WH; Pearson, SK; Rosalen, PL, 1996) |
"Erythritol is a sugar alcohol produced by Aureobasidium sp." | 1.28 | Noncariogenicity of erythritol as a substrate. ( Hirasawa, M; Ikeda, T; Kawanabe, J; Oda, T; Takeuchi, T, 1992) |
Timeframe | Studies, this research(%) | All Research% |
---|---|---|
pre-1990 | 36 (24.49) | 18.7374 |
1990's | 33 (22.45) | 18.2507 |
2000's | 28 (19.05) | 29.6817 |
2010's | 38 (25.85) | 24.3611 |
2020's | 12 (8.16) | 2.80 |
Authors | Studies |
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Pourhajibagher, M | 1 |
Keshavarz Valian, N | 1 |
Bahador, A | 1 |
Fan, M | 1 |
Li, M | 2 |
Yang, Y | 2 |
Weir, MD | 10 |
Liu, Y | 3 |
Zhou, X | 5 |
Liang, K | 1 |
Li, J | 2 |
Xu, HHK | 5 |
Habibi, P | 1 |
Yazdi, FT | 1 |
Mortazavi, SA | 1 |
Farajollahi, MM | 1 |
Ma, Q | 1 |
Pan, Y | 1 |
Chen, Y | 1 |
Yu, S | 1 |
Huang, J | 1 |
Gong, T | 1 |
Zhang, Q | 1 |
Sun, Q | 1 |
Zou, J | 1 |
Li, Y | 1 |
Chen, H | 1 |
Xie, S | 1 |
Gao, J | 1 |
He, L | 1 |
Luo, W | 1 |
Tang, Y | 1 |
Oates, TW | 3 |
Yang, D | 1 |
Kondo, S | 1 |
Hazama, H | 1 |
Tomioka, Y | 1 |
Mine, A | 1 |
Yamaguchi, S | 1 |
Okumura, S | 1 |
Tanimoto, H | 1 |
Yasuo, K | 1 |
Yoshikawa, K | 1 |
Yamamoto, K | 1 |
Awazu, K | 1 |
Wang, Y | 4 |
Zeng, Y | 3 |
Feng, Z | 3 |
Li, Z | 3 |
Jiang, X | 3 |
Han, S | 3 |
Washio, J | 3 |
Takahashi, N | 5 |
Zhang, L | 3 |
Wong, PYW | 3 |
Lim, SL | 3 |
Loi, STY | 3 |
Mei, ML | 3 |
Li, KC | 3 |
Aziz, S | 3 |
Ekambaram, M | 3 |
Nedeljkovic, I | 3 |
Doulabi, BZ | 3 |
Abdelaziz, M | 3 |
Feilzer, AJ | 3 |
Exterkate, RAM | 3 |
Szafert, S | 3 |
Gulia, N | 3 |
Krejci, I | 3 |
Kleverlaan, CJ | 3 |
Ren, S | 1 |
Xia, M | 1 |
Deng, Y | 1 |
Zuo, Y | 1 |
Lei, L | 1 |
Hu, T | 1 |
Sterzenbach, T | 1 |
Hannig, C | 1 |
Hertel, S | 1 |
Ekrikaya, S | 1 |
Yilmaz, E | 1 |
Arslan, S | 1 |
Karaaslan, R | 1 |
Ildiz, N | 1 |
Celik, C | 1 |
Ocsoy, I | 1 |
Nascimento, MM | 1 |
Alvarez, AJ | 1 |
Huang, X | 1 |
Browngardt, C | 1 |
Jenkins, R | 1 |
Sinhoreti, MC | 1 |
Ribeiro, APD | 1 |
Dilbone, DA | 1 |
Richards, VP | 1 |
Garrett, TJ | 1 |
Burne, RA | 1 |
Xue, Y | 1 |
Lu, Q | 1 |
Tian, Y | 1 |
Cheng, L | 6 |
Ren, B | 2 |
Choi, HW | 1 |
Um, SH | 1 |
Rhee, SH | 1 |
Liang, J | 1 |
Wu, T | 1 |
Peng, X | 1 |
Yang, G | 1 |
Zhang, S | 1 |
Al-Dulaijan, YA | 1 |
Melo, MAS | 2 |
Liu, H | 1 |
Wang, L | 2 |
Cusicanqui Méndez, DA | 1 |
Gutierres, E | 1 |
José Dionisio, E | 1 |
Afonso Rabelo Buzalaf, M | 1 |
Cardoso Oliveira, R | 1 |
Andrade Moreira Machado, MA | 1 |
Cruvinel, T | 1 |
Wang, H | 1 |
Wang, S | 1 |
Jiang, Y | 1 |
Elgamily, HM | 1 |
Gamal, AA | 1 |
Saleh, SAA | 1 |
Abdel Wahab, WA | 1 |
Hashem, AM | 1 |
Esawy, MA | 1 |
Amaechi, BT | 1 |
Porteous, N | 1 |
Ramalingam, K | 1 |
Mensinkai, PK | 1 |
Ccahuana Vasquez, RA | 1 |
Sadeghpour, A | 1 |
Nakamoto, T | 1 |
Runnel, R | 1 |
Mäkinen, KK | 1 |
Honkala, S | 1 |
Olak, J | 1 |
Mäkinen, PL | 1 |
Nõmmela, R | 1 |
Vahlberg, T | 1 |
Honkala, E | 1 |
Saag, M | 1 |
Ilie, O | 1 |
van Turnhout, AG | 1 |
van Loosdrecht, MC | 1 |
Picioreanu, C | 1 |
Newby, EE | 1 |
Martinez-Mier, EA | 1 |
Hara, A | 1 |
Lippert, F | 4 |
Kelly, SA | 1 |
Fleming, N | 1 |
Butler, A | 3 |
Bosma, ML | 1 |
Zero, DT | 2 |
Al-Khateeb, SN | 1 |
Tarazi, SJ | 1 |
Al Maaitah, EF | 1 |
Al-Batayneh, OB | 1 |
Abu Alhaija, ES | 1 |
Cardoso, CA | 1 |
de Castilho, AR | 1 |
Salomão, PM | 1 |
Costa, EN | 1 |
Magalhães, AC | 2 |
Buzalaf, MA | 3 |
Schwendicke, F | 1 |
Eggers, K | 1 |
Meyer-Lueckel, H | 1 |
Dörfer, C | 1 |
Kovalev, A | 1 |
Gorb, S | 1 |
Paris, S | 1 |
Do, T | 1 |
Sheehy, EC | 1 |
Mulli, T | 1 |
Hughes, F | 1 |
Beighton, D | 2 |
Wu, J | 1 |
Zhou, H | 1 |
Melo, MA | 3 |
Levine, ED | 1 |
Xu, HH | 5 |
Zhang, N | 1 |
Chen, C | 1 |
Bai, Y | 1 |
Delecrode, TR | 1 |
Siqueira, WL | 1 |
Zaidan, FC | 1 |
Bellini, MR | 1 |
Moffa, EB | 1 |
Mussi, MC | 1 |
Xiao, Y | 1 |
Wang, X | 1 |
Wang, B | 1 |
Junling, W | 1 |
Qiang, Z | 1 |
Ruinan, S | 1 |
Ting, Z | 1 |
Jianhua, G | 1 |
Chuanjian, Z | 1 |
Orrego, S | 1 |
Arola, DD | 1 |
Willems, HM | 1 |
Kos, K | 1 |
Jabra-Rizk, MA | 1 |
Krom, BP | 1 |
Shimizu, K | 1 |
Igarashi, K | 1 |
de Carvalho, FG | 1 |
de Fucio, SB | 1 |
Sinhoreti, MA | 1 |
Correr-Sobrinho, L | 1 |
Puppin-Rontani, RM | 1 |
Shigetani, Y | 1 |
Takenaka, S | 1 |
Okamoto, A | 1 |
Abu-Bakr, N | 1 |
Iwaku, M | 1 |
Okiji, T | 1 |
Azrak, B | 2 |
Callaway, A | 3 |
Willershausen, B | 3 |
Ebadi, S | 1 |
Gleissner, C | 2 |
Ahmed, AA | 1 |
García-Godoy, F | 2 |
Kunzelmann, KH | 2 |
Klinke, T | 1 |
Kneist, S | 2 |
de Soet, JJ | 1 |
Kuhlisch, E | 1 |
Mauersberger, S | 1 |
Forster, A | 1 |
Klimm, W | 1 |
Chaussain, C | 1 |
Opsahl Vital, S | 1 |
Viallon, V | 1 |
Vermelin, L | 1 |
Haignere, C | 1 |
Sixou, M | 1 |
Lasfargues, JJ | 1 |
Nakata, K | 1 |
Nikaido, T | 1 |
Ikeda, M | 1 |
Foxton, RM | 1 |
Tagami, J | 1 |
Moron, BM | 1 |
Comar, LP | 1 |
Wiegand, A | 2 |
Buchalla, W | 1 |
McCLURE, FJ | 2 |
HEWITT, WL | 1 |
Kang, KH | 1 |
Lee, JS | 1 |
Yoo, M | 1 |
Jin, I | 1 |
Jadamus-Stöcker, J | 1 |
Schmidt, F | 1 |
Rupf, S | 1 |
Wicht, M | 1 |
Thiede, B | 1 |
Lynch, RJ | 2 |
Churchley, D | 1 |
Kearns, S | 1 |
Thomas, GV | 1 |
Badrock, TC | 1 |
Cooper, L | 1 |
Higham, SM | 1 |
Zhang, K | 1 |
Xu, SM | 1 |
Chen, Q | 1 |
Misra, S | 1 |
Raghuwanshi, S | 1 |
Gupta, P | 1 |
Saxena, RK | 1 |
Choi, CH | 1 |
Ha, MO | 1 |
Youn, HJ | 1 |
Jeong, SS | 2 |
Iijima, Y | 1 |
Sohn, W | 1 |
Hong, SJ | 2 |
Schmidlin, PR | 1 |
Sener, B | 1 |
Attin, T | 1 |
Tsapok, PI | 1 |
Imbriakov, KV | 1 |
Chuchkova, MR | 1 |
Mohanty, B | 1 |
Dadlani, D | 1 |
Mahoney, D | 1 |
Mann, AB | 1 |
Hsia, RC | 1 |
Rodrigues, LK | 1 |
Liu, L | 1 |
Yue, S | 1 |
Jiang, H | 1 |
Lu, T | 1 |
Qian, H | 1 |
Li, C | 1 |
Yue, J | 1 |
Smith, DJ | 1 |
Lam, A | 1 |
Barnes, LA | 1 |
King, WF | 1 |
Peacock, Z | 1 |
Wise, DL | 1 |
Trantolo, DJ | 1 |
Taubman, MA | 1 |
Issa, AI | 1 |
Preston, KP | 1 |
Preston, AJ | 1 |
Toumba, KJ | 1 |
Duggal, MS | 1 |
BREITNER, W | 1 |
BENTLEY, KD | 2 |
HALDI, J | 2 |
LAW, ML | 2 |
RAMSEY, DA | 2 |
WYNN, W | 2 |
VAIN, SI | 1 |
TARNOPOL'SKAIA, AM | 1 |
Banerjee, A | 1 |
Gilmour, A | 1 |
Kidd, E | 1 |
Watson, T | 1 |
Twetman, S | 1 |
Stecksén-Blicks, C | 1 |
Song, KB | 1 |
Clapper, WE | 1 |
Heatherman, ME | 1 |
Toi, CS | 1 |
Cleaton-Jones, P | 1 |
Ruby, J | 1 |
Goldner, M | 1 |
Krämer, N | 1 |
Häberlein, I | 1 |
Meier, B | 1 |
Frankenberger, R | 1 |
Bretz, WA | 1 |
Corby, PM | 1 |
Costa, S | 1 |
Quadros, M | 1 |
Tavares, VS | 1 |
Moreira, G | 1 |
Filho, MR | 1 |
Weyant, RJ | 1 |
ZIPKIN, I | 1 |
BOYD, JD | 1 |
CHEYNE, VD | 1 |
WESSELS, KE | 1 |
PEARLMAN, S | 1 |
SPRAGUE, WG | 1 |
BEST, RC | 1 |
GRANADOS, H | 1 |
GLAVIND, J | 1 |
DAM, H | 1 |
Wefel, JS | 2 |
Harless, JD | 1 |
Kuboki, Y | 1 |
Liu, CF | 1 |
Fusayama, T | 1 |
Feagin, FF | 1 |
Panopoulos, P | 1 |
Gazelius, B | 1 |
Olgart, L | 1 |
Featherstone, JD | 2 |
Rodgers, BE | 1 |
Shrestha, BM | 1 |
Mundorff, SA | 1 |
Bibby, BG | 1 |
Dalstein, JM | 1 |
Ribes, G | 1 |
Campo, P | 1 |
Loubatières-Mariani, MM | 1 |
Hojo, S | 1 |
Komatsu, M | 1 |
Okuda, R | 1 |
Yamada, T | 1 |
Chestnutt, IG | 1 |
MacFarlane, TW | 2 |
Stephen, KW | 2 |
Margolis, HC | 8 |
Moreno, EC | 6 |
Tanaka, M | 1 |
Zhang, YP | 2 |
van Houte, J | 2 |
Tanaka, H | 1 |
Tamura, M | 1 |
Kikuchi, K | 1 |
Kuwata, F | 1 |
Hirano, Y | 1 |
Hayashi, K | 1 |
van Loveren, C | 1 |
Buijs, JF | 1 |
ten Cate, JM | 3 |
Hartemink, R | 1 |
Quataert, MC | 1 |
van Laere, KM | 1 |
Nout, MJ | 1 |
Rombouts, FM | 1 |
Assinder, SJ | 2 |
Eynstone, LV | 1 |
Shellis, RP | 1 |
Dibdin, GH | 1 |
Hoelscher, GL | 1 |
Hudson, MC | 1 |
Popiel, HA | 1 |
Rosalen, PL | 1 |
Pearson, SK | 1 |
Bowen, WH | 1 |
Grossman, ES | 2 |
Matejka, JM | 2 |
Niederman, R | 1 |
Zhang, J | 1 |
Kashket, S | 1 |
Coogan, MM | 1 |
Motlekar, HB | 1 |
Millar, BJ | 1 |
Abiden, F | 1 |
Nicholson, JW | 2 |
Bradshaw, DJ | 1 |
Marsh, PD | 1 |
Czarnecka, B | 1 |
Limanowska-Shaw, H | 1 |
Hillman, JD | 1 |
Brooks, TA | 1 |
Michalek, SM | 1 |
Harmon, CC | 1 |
Snoep, JL | 1 |
van Der Weijden, CC | 1 |
Kent, RL | 2 |
Neta, T | 1 |
Takada, K | 1 |
Hirasawa, M | 2 |
Peltroche-Llacsahuanga, H | 1 |
Hauk, CJ | 1 |
Kock, R | 1 |
Lampert, F | 1 |
Lütticken, R | 1 |
Haase, G | 1 |
Gao, XJ | 2 |
Deng, DM | 1 |
Geng, QM | 1 |
Sheng, JY | 1 |
Liu, Z | 1 |
Dong, Y | 1 |
Gao, X | 2 |
Yue, L | 1 |
Huis in 't Veld, JH | 1 |
Fan, Y | 1 |
Savarino, L | 1 |
Saponara Teutonico, A | 1 |
Tarabusi, C | 1 |
Breschi, L | 1 |
Prati, C | 1 |
Kawanabe, J | 1 |
Takeuchi, T | 1 |
Oda, T | 1 |
Ikeda, T | 1 |
Blake-Haskins, JC | 1 |
Mellberg, JR | 1 |
Snyder, C | 1 |
Yue, SL | 3 |
Zhou, XD | 1 |
Nammour, S | 1 |
Renneboog-Squilbin, C | 1 |
Nyssen-Behets, C | 1 |
Klont, B | 1 |
Damen, JJ | 1 |
Carey, CM | 2 |
Vogel, GL | 2 |
Chow, LC | 2 |
Kato, K | 1 |
Rahbek, I | 1 |
Fu, J | 1 |
Proskin, HM | 1 |
van Dorp, CS | 1 |
Exterkate, RA | 1 |
Setsu, E | 1 |
Carlsson, J | 1 |
Allenspach-Petrzilka, GE | 1 |
Guggenheim, B | 1 |
Lutz, F | 1 |
Gregory, TM | 1 |
Brown, WE | 1 |
Hoppenbrouwers, PM | 1 |
Driessens, FC | 1 |
Edmunds, DH | 1 |
Whittaker, DK | 1 |
Green, RM | 1 |
Lembke, A | 1 |
Alsen-Hinrichs, C | 1 |
Pause, B | 1 |
Kidd, EA | 1 |
Joyston-Bechal, S | 1 |
Creanor, SL | 1 |
Mackenzie, D | 1 |
Weetman, DA | 1 |
Strang, R | 1 |
White, DJ | 1 |
Yue, JQ | 1 |
Minah, GE | 1 |
McEnery, MC | 1 |
Flores, JA | 1 |
Strübig, W | 1 |
Mao, Y | 1 |
Ranke, E | 1 |
Ranke, B | 1 |
Murphy, BJ | 1 |
Phankosol, P | 1 |
Ettinger, RL | 1 |
Hicks, MJ | 1 |
van der Hoeven, JS | 1 |
Trial | Phase | Enrollment | Study Type | Start Date | Status | ||
---|---|---|---|---|---|---|---|
Effect of Erythritol and Xylitol on Dental Caries Prevention in Children[NCT01062633] | Phase 2/Phase 3 | 450 participants (Anticipated) | Interventional | 2008-01-31 | Recruiting | ||
Effect of the Consumption of Beverages Added With Stevia Rebaudiana on Oral pH and Dental Biofilm in Adolescents[NCT05852145] | Phase 1/Phase 2 | 52 participants (Anticipated) | Interventional | 2023-10-31 | Not yet recruiting | ||
Effects of Carbonated Beverage Consumption on Oral pH and Bacterial Proliferation in Adolescents: A Randomized Crossover Clinical Trial.[NCT05437874] | Phase 1 | 18 participants (Actual) | Interventional | 2018-01-18 | Completed | ||
A Clinical Study to Evaluate Experimental Children's Toothpastes in an In-Situ Caries Model[NCT01607411] | Phase 3 | 55 participants (Actual) | Interventional | 2012-02-29 | Completed | ||
Comparison of Three Orthodontic Bonding Systems in White Spot Lesion Development: A Randomized Clinical Trial[NCT05738356] | 75 participants (Actual) | Interventional | 2021-12-10 | Active, not recruiting | |||
Comparison of the Remineralization Potential of an Optimized Fluoride Dentifrice With a Control Fluoride Dentifrice Using an in Situ Caries Model[NCT06010732] | Phase 3 | 65 participants (Anticipated) | Interventional | 2023-10-02 | Recruiting | ||
Prevention of Enamel Demineralization in Fixed Appliance Orthodontic Patients Using UDMA-K18 Sealant to Prevent Microbial Attachment Compared to a UDMA Control and no Sealant, a Randomized Split Mouth Clinical Trial[NCT03306433] | 16 participants (Actual) | Interventional | 2018-01-08 | Completed | |||
[information is prepared from clinicaltrials.gov, extracted Sep-2024] |
Surface microhardness recovery (SMHR) test was used to assess the changes in mineralization status of enamel specimens using a Wilson 2100 Hardness tester. SMHR was determined by measuring the length of the indentations of enamel specimens. An increase in the indentation length compared to the baseline indicates softening while decrease in the indentation length represents rehardening of enamel surface. Percent SMHR was calculated from indentation values of enamel specimens at baseline (B), after in-situ hardening (R) and after first demineralization challenge (D1) using formula: [(D1-R)/ (D1-B)]*100. (NCT01607411)
Timeframe: Baseline to 4 hours
Intervention | %SMHR (Mean) |
---|---|
NaF Toothpaste (1426 Ppm F) | 30.72 |
NaF Toothpaste (1000 Ppm F) | 29.49 |
NaF Toothpaste (500 Ppm F) | 28.29 |
Enamel fluoride uptake was determined using the microdrill enamel biopsy technique. The amount of fluoride uptake by enamel was calculated based on amount of F divided by volume of the enamel cores and expressed as micrograms (μg)* F/centimeters(cm)^2. Difference between treatments was calculated with respect to F uptake by enamel. (NCT01607411)
Timeframe: Baseline to 4 hours
Intervention | μg*F/cm^2 (Mean) |
---|---|
NaF Toothpaste (1426 Ppm F) | 1.76 |
NaF Toothpaste (1000 Ppm F) | 1.77 |
NaF Toothpaste (500 Ppm F) | 1.47 |
Placebo Toothpaste (0 Ppm F) | 0.98 |
Changes in mineral content of enamel specimens exposed to dietary erosive challenge were determined by measuring the length of the indentations. Decrease in the indentation length compared to the baseline indicates hardening of enamel surface. Enamel specimens were exposed to second erosion challenge to determine NAR which compared the indentations values of sound enamel specimens at baseline (B), first demineralization challenge (D1) and second demineralization challenge (D2). Percent NAR was calculated by formula: [(D1-D2)/ (D1-B)]*100. (NCT01607411)
Timeframe: Baseline to 4 hours
Intervention | %NAR (Mean) |
---|---|
NaF Toothpaste (1426 Ppm F) | -19.72 |
NaF Toothpaste (1000 Ppm F) | -19.52 |
NaF Toothpaste (500 Ppm F) | -25.82 |
Placebo Toothpaste (0 Ppm F) | -54.38 |
Surface microhardness recovery (SMHR) test was used to assess the changes in mineralization status of enamel specimens using a Wilson 2100 Hardness tester. SMHR was determined by measuring the length of the indentations of enamel specimens. An increase in the indentation length compared to the baseline indicates softening while decrease in the indentation length represents rehardening of enamel surface. Percent SMHR was calculated from indentation values of enamel specimens at baseline (B), after in-situ hardening (R) and after first demineralization challenge (D1) using formula: [(D1-R)/ (D1-B)]*100. (NCT01607411)
Timeframe: Baseline to 4 hours
Intervention | %SMHR (Mean) |
---|---|
NaF Toothpaste (1426 Ppm F) | 30.72 |
NaF Toothpaste (1000 Ppm F) | 29.49 |
NaF Toothpaste (500 Ppm F) | 28.29 |
Placebo Toothpaste (0 Ppm F) | 25.13 |
The mineral density immediately below the surface of the tooth will lower if left unprotected to some extent. (NCT03306433)
Timeframe: Visit Window: 3-4 weeks.
Intervention | Canary Number (Mean) |
---|---|
UDMA-K18 | 23.424 |
UDMA-control | 31.125 |
Adhesive Control | 35.563 |
The WSL Index is from 0 (no lesion) to 4 (severe lesion) (NCT03306433)
Timeframe: Visit Window: 3-4 weeks.
Intervention | White spot Index (Median) |
---|---|
UDMA-K18 | 0 |
UDMA-control | 2 |
Adhesive Control | 2 |
4 reviews available for lactic acid and Caries, Dental
Article | Year |
---|---|
Composition and cariogenic potential of dental plaque fluid.
Topics: Calcium Phosphates; Cariogenic Agents; Dental Calculus; Dental Caries; Dental Plaque; Exudates and T | 1994 |
Short-chain carboxylic-acid-stimulated, PMN-mediated gingival inflammation.
Topics: Bacteria, Anaerobic; Butyrates; Butyric Acid; Cytokines; Dental Caries; Endothelium; Epithelium; Fib | 1997 |
[The role of lactic acid bacteria in nutrition and health].
Topics: Dental Caries; Dental Plaque; Food Microbiology; Humans; Lactic Acid; Lactobacillus; Lactococcus; Mo | 1992 |
Microbial aspects of frequent intake of products with high sugar concentrations.
Topics: Bacteria; Dental Caries; Dietary Carbohydrates; Feeding Behavior; Fermentation; Humans; Hydrogen-Ion | 1989 |
9 trials available for lactic acid and Caries, Dental
Article | Year |
---|---|
Metabolic Profile of Supragingival Plaque Exposed to Arginine and Fluoride.
Topics: Adult; Arginine; Dental Caries; Dental Plaque; Double-Blind Method; Fluorides; Humans; Hydrogen-Ion | 2019 |
Effect of toothpaste containing arginine on dental plaque-A randomized controlled in situ study.
Topics: Activation, Metabolic; Adult; Arginine; Bacteria; Biofilms; Biomass; Cross-Over Studies; Dental Cari | 2017 |
Remineralization of artificial enamel lesions by theobromine.
Topics: Calcium; Cariostatic Agents; Dental Caries; Dental Enamel; Electron Probe Microanalysis; Hardness; H | 2013 |
Effect of three-year consumption of erythritol, xylitol and sorbitol candies on various plaque and salivary caries-related variables.
Topics: Acetic Acid; Bacterial Load; Calcium; Candy; Child; Cohort Studies; Dental Caries; Dental Plaque; Do | 2013 |
A randomised clinical study to evaluate experimental children's toothpastes in an in-situ palatal caries model in children aged 11-14 years.
Topics: Adolescent; Cariostatic Agents; Child; Cross-Over Studies; Dental Caries; Dental Enamel; Dose-Respon | 2013 |
[Sugar substitute products impact on oral fluid biochemical properties].
Topics: Adolescent; Carbohydrates; Chewing Gum; Dental Caries; Humans; Lactic Acid; Lipid Peroxidation; Male | 2012 |
A study investigating the formation of artificial sub-surface enamel caries-like lesions in deciduous and permanent teeth in the presence and absence of fluoride.
Topics: Cariogenic Agents; Dental Caries; Fluorides; Humans; Image Processing, Computer-Assisted; Lactic Aci | 2003 |
Effect of xylitol-containing chewing gums on lactic acid production in dental plaque from caries active pre-school children.
Topics: Cariostatic Agents; Chewing Gum; Child, Preschool; Cross-Over Studies; Dental Caries; Dental Plaque; | 2003 |
Histological features of artificial secondary caries adjacent to amalgam restorations.
Topics: Bicuspid; Chi-Square Distribution; Dental Alloys; Dental Amalgam; Dental Caries; Dental Caries Susce | 1999 |
134 other studies available for lactic acid and Caries, Dental
Article | Year |
---|---|
Theranostic nanoplatforms of emodin-chitosan with blue laser light on enhancing the anti-biofilm activity of photodynamic therapy against Streptococcus mutans biofilms on the enamel surface.
Topics: Anti-Bacterial Agents; Anti-Infective Agents; Biofilms; Chitosan; Dental Caries; Dental Enamel; Emod | 2022 |
Dual-functional adhesive containing amorphous calcium phosphate nanoparticles and dimethylaminohexadecyl methacrylate promoted enamel remineralization in a biofilm-challenged environment.
Topics: Anti-Bacterial Agents; Biofilms; Calcium Phosphates; Dental Caries; Dental Cements; Dental Enamel; H | 2022 |
Effects of free and nano-encapsulated bovine lactoferrin on the viability and acid production by Streptococcus mutans biofilms.
Topics: Anti-Infective Agents; Biofilms; Cariostatic Agents; Dental Caries; Humans; Lactic Acid; Lactoferrin | 2022 |
Acetylation of Lactate Dehydrogenase Negatively Regulates the Acidogenicity of Streptococcus mutans.
Topics: Acetylation; Acetyltransferases; Animals; Dental Caries; L-Lactate Dehydrogenase; Lactic Acid; Lysin | 2022 |
Flavonoid Baicalein Suppresses Oral Biofilms and Protects Enamel Hardness to Combat Dental Caries.
Topics: Biofilms; Candida albicans; Catechin; Chlorhexidine; Dental Caries; Dental Enamel; Flavanones; Flavo | 2022 |
Demonstration of an optical dentin hardness measuring device using bovine dentin with different demineralization times.
Topics: Animals; Cattle; Dental Caries; Dentin; Hardness; Lactic Acid; Optical Devices; Root Caries; Tooth D | 2022 |
Combined Treatment with Fluoride and Antimicrobial Peptide GH12 Efficiently Controls Caries in vitro and in vivo.
Topics: Animals; Antimicrobial Peptides; Biofilms; Cattle; Dental Caries; Dental Caries Susceptibility; Dent | 2022 |
Combined Treatment with Fluoride and Antimicrobial Peptide GH12 Efficiently Controls Caries in vitro and in vivo.
Topics: Animals; Antimicrobial Peptides; Biofilms; Cattle; Dental Caries; Dental Caries Susceptibility; Dent | 2022 |
Combined Treatment with Fluoride and Antimicrobial Peptide GH12 Efficiently Controls Caries in vitro and in vivo.
Topics: Animals; Antimicrobial Peptides; Biofilms; Cattle; Dental Caries; Dental Caries Susceptibility; Dent | 2022 |
Combined Treatment with Fluoride and Antimicrobial Peptide GH12 Efficiently Controls Caries in vitro and in vivo.
Topics: Animals; Antimicrobial Peptides; Biofilms; Cattle; Dental Caries; Dental Caries Susceptibility; Dent | 2022 |
Combined Treatment with Fluoride and Antimicrobial Peptide GH12 Efficiently Controls Caries in vitro and in vivo.
Topics: Animals; Antimicrobial Peptides; Biofilms; Cattle; Dental Caries; Dental Caries Susceptibility; Dent | 2022 |
Combined Treatment with Fluoride and Antimicrobial Peptide GH12 Efficiently Controls Caries in vitro and in vivo.
Topics: Animals; Antimicrobial Peptides; Biofilms; Cattle; Dental Caries; Dental Caries Susceptibility; Dent | 2022 |
Combined Treatment with Fluoride and Antimicrobial Peptide GH12 Efficiently Controls Caries in vitro and in vivo.
Topics: Animals; Antimicrobial Peptides; Biofilms; Cattle; Dental Caries; Dental Caries Susceptibility; Dent | 2022 |
Combined Treatment with Fluoride and Antimicrobial Peptide GH12 Efficiently Controls Caries in vitro and in vivo.
Topics: Animals; Antimicrobial Peptides; Biofilms; Cattle; Dental Caries; Dental Caries Susceptibility; Dent | 2022 |
Combined Treatment with Fluoride and Antimicrobial Peptide GH12 Efficiently Controls Caries in vitro and in vivo.
Topics: Animals; Antimicrobial Peptides; Biofilms; Cattle; Dental Caries; Dental Caries Susceptibility; Dent | 2022 |
A comparative study of two chemical models for creating subsurface caries lesions on aprismatic and prismatic enamel.
Topics: Acetic Acid; Animals; Cattle; Dental Caries; Dental Caries Susceptibility; Dental Enamel; Lactic Aci | 2023 |
A comparative study of two chemical models for creating subsurface caries lesions on aprismatic and prismatic enamel.
Topics: Acetic Acid; Animals; Cattle; Dental Caries; Dental Caries Susceptibility; Dental Enamel; Lactic Aci | 2023 |
A comparative study of two chemical models for creating subsurface caries lesions on aprismatic and prismatic enamel.
Topics: Acetic Acid; Animals; Cattle; Dental Caries; Dental Caries Susceptibility; Dental Enamel; Lactic Aci | 2023 |
A comparative study of two chemical models for creating subsurface caries lesions on aprismatic and prismatic enamel.
Topics: Acetic Acid; Animals; Cattle; Dental Caries; Dental Caries Susceptibility; Dental Enamel; Lactic Aci | 2023 |
A comparative study of two chemical models for creating subsurface caries lesions on aprismatic and prismatic enamel.
Topics: Acetic Acid; Animals; Cattle; Dental Caries; Dental Caries Susceptibility; Dental Enamel; Lactic Aci | 2023 |
A comparative study of two chemical models for creating subsurface caries lesions on aprismatic and prismatic enamel.
Topics: Acetic Acid; Animals; Cattle; Dental Caries; Dental Caries Susceptibility; Dental Enamel; Lactic Aci | 2023 |
A comparative study of two chemical models for creating subsurface caries lesions on aprismatic and prismatic enamel.
Topics: Acetic Acid; Animals; Cattle; Dental Caries; Dental Caries Susceptibility; Dental Enamel; Lactic Aci | 2023 |
A comparative study of two chemical models for creating subsurface caries lesions on aprismatic and prismatic enamel.
Topics: Acetic Acid; Animals; Cattle; Dental Caries; Dental Caries Susceptibility; Dental Enamel; Lactic Aci | 2023 |
A comparative study of two chemical models for creating subsurface caries lesions on aprismatic and prismatic enamel.
Topics: Acetic Acid; Animals; Cattle; Dental Caries; Dental Caries Susceptibility; Dental Enamel; Lactic Aci | 2023 |
Cytotoxicity and anti-biofilm properties of novel hybrid-glass-based caries infiltrant.
Topics: Animals; Biofilms; Dental Caries; Dental Caries Susceptibility; Glass; Lactic Acid; Mice | 2022 |
Cytotoxicity and anti-biofilm properties of novel hybrid-glass-based caries infiltrant.
Topics: Animals; Biofilms; Dental Caries; Dental Caries Susceptibility; Glass; Lactic Acid; Mice | 2022 |
Cytotoxicity and anti-biofilm properties of novel hybrid-glass-based caries infiltrant.
Topics: Animals; Biofilms; Dental Caries; Dental Caries Susceptibility; Glass; Lactic Acid; Mice | 2022 |
Cytotoxicity and anti-biofilm properties of novel hybrid-glass-based caries infiltrant.
Topics: Animals; Biofilms; Dental Caries; Dental Caries Susceptibility; Glass; Lactic Acid; Mice | 2022 |
Cytotoxicity and anti-biofilm properties of novel hybrid-glass-based caries infiltrant.
Topics: Animals; Biofilms; Dental Caries; Dental Caries Susceptibility; Glass; Lactic Acid; Mice | 2022 |
Cytotoxicity and anti-biofilm properties of novel hybrid-glass-based caries infiltrant.
Topics: Animals; Biofilms; Dental Caries; Dental Caries Susceptibility; Glass; Lactic Acid; Mice | 2022 |
Cytotoxicity and anti-biofilm properties of novel hybrid-glass-based caries infiltrant.
Topics: Animals; Biofilms; Dental Caries; Dental Caries Susceptibility; Glass; Lactic Acid; Mice | 2022 |
Cytotoxicity and anti-biofilm properties of novel hybrid-glass-based caries infiltrant.
Topics: Animals; Biofilms; Dental Caries; Dental Caries Susceptibility; Glass; Lactic Acid; Mice | 2022 |
Cytotoxicity and anti-biofilm properties of novel hybrid-glass-based caries infiltrant.
Topics: Animals; Biofilms; Dental Caries; Dental Caries Susceptibility; Glass; Lactic Acid; Mice | 2022 |
A Chinese herb preparation, honokiol, inhibits Streptococcus mutans biofilm formation.
Topics: Biofilms; Dental Caries; Humans; Lactic Acid; Lignans; Streptococcus mutans | 2023 |
Influence of Consumption of Nitrate-rich Beetroot Juice on Lactate Production in Saliva and Oral Biofilm - A Clinical Trial.
Topics: Biofilms; Dental Caries; Humans; Lactic Acid; Nitrates; Nitrites; Saliva | 2023 |
Dentin bond strength and antimicrobial activities of universal adhesives containing silver nanoparticles synthesized with Rosa canina extract.
Topics: Adhesives; Anti-Bacterial Agents; Anti-Infective Agents; Dental Bonding; Dental Caries; Dental Cemen | 2023 |
Preparation of fluoride-loaded microcapsules for anticariogenic bacterial growth using a coaxial ultrasonic atomizer.
Topics: Capsules; Dental Caries; Fluorides; Lactic Acid; Polyglycolic Acid; Polylactic Acid-Polyglycolic Aci | 2018 |
The anti-caries effects of dental adhesive resin influenced by the position of functional groups in quaternary ammonium monomers.
Topics: Animals; Anti-Bacterial Agents; Biocompatible Materials; Biofilms; Biomechanical Phenomena; Dental C | 2018 |
Novel rechargeable calcium phosphate nanocomposite with antibacterial activity to suppress biofilm acids and dental caries.
Topics: Anti-Bacterial Agents; Benzhydryl Compounds; Benzoates; Biofilms; Calcium Phosphates; Camphor; Colon | 2018 |
Curcumin-mediated antimicrobial photodynamic therapy reduces the viability and vitality of infected dentin caries microcosms.
Topics: Animals; Biofilms; Cattle; Curcumin; Dental Caries; Dentin; Dose-Response Relationship, Drug; Lactic | 2018 |
Novel dental composite with capability to suppress cariogenic species and promote non-cariogenic species in oral biofilms.
Topics: Biofilms; Colony Count, Microbial; Dental Caries; Dental Materials; Lactic Acid; Methacrylates; Mout | 2019 |
Microbiological and environmental assessment of human oral dental plaque isolates.
Topics: Animals; Anti-Bacterial Agents; Bacillaceae; Bacillus; Bacillus subtilis; Bacteria; Bacterial Adhesi | 2019 |
Numerical modelling of tooth enamel subsurface lesion formation induced by dental plaque.
Topics: Acid-Base Equilibrium; Algorithms; Cariostatic Agents; Dental Caries; Dental Enamel; Dental Enamel S | 2014 |
Numerical modelling of tooth enamel subsurface lesion formation induced by dental plaque.
Topics: Acid-Base Equilibrium; Algorithms; Cariostatic Agents; Dental Caries; Dental Enamel; Dental Enamel S | 2014 |
Numerical modelling of tooth enamel subsurface lesion formation induced by dental plaque.
Topics: Acid-Base Equilibrium; Algorithms; Cariostatic Agents; Dental Caries; Dental Enamel; Dental Enamel S | 2014 |
Numerical modelling of tooth enamel subsurface lesion formation induced by dental plaque.
Topics: Acid-Base Equilibrium; Algorithms; Cariostatic Agents; Dental Caries; Dental Enamel; Dental Enamel S | 2014 |
Does acid etching enhance remineralisation of arrested white spot lesions?
Topics: Acid Etching, Dental; Cariostatic Agents; Caseins; Dental Caries; Dental Enamel; Fluorescence; Fluor | 2014 |
Effect of xylitol varnishes on remineralization of artificial enamel caries lesions in vitro.
Topics: Animals; Cariostatic Agents; Cattle; Dental Caries; Dental Enamel; Fluorides, Topical; Hardness; Hyd | 2014 |
In vitro Induction of residual caries lesions in dentin: comparative mineral loss and nano-hardness analysis.
Topics: Acetic Acid; Biofilms; Citric Acid; Dental Caries; Dentin; Diphosphonates; Edetic Acid; Elastic Modu | 2015 |
Transcriptomic analysis of three Veillonella spp. present in carious dentine and in the saliva of caries-free individuals.
Topics: Adult; Bacterial Proteins; Dental Caries; Dentin; Female; Humans; Lactic Acid; Male; Saliva; Succini | 2015 |
Effect of dimethylaminohexadecyl methacrylate mass fraction on fracture toughness and antibacterial properties of CaP nanocomposite.
Topics: Anti-Bacterial Agents; Bacteria; Biofilms; Calcium Phosphates; Composite Resins; Dental Caries; Dent | 2015 |
Antibacterial and protein-repellent orthodontic cement to combat biofilms and white spot lesions.
Topics: Anti-Bacterial Agents; Bacteria; Bacterial Adhesion; Biofilms; Dental Bonding; Dental Caries; Dental | 2015 |
Identification of acid-resistant proteins in acquired enamel pellicle.
Topics: Adolescent; Adult; Citric Acid; Cross-Over Studies; Cystatin B; Dental Caries; Dental Enamel; Dental | 2015 |
Antibacterial orthodontic cement to combat biofilm and white spot lesions.
Topics: Acrylic Resins; Adhesiveness; Aluminum Silicates; Anti-Bacterial Agents; Bacterial Load; Biofilms; C | 2015 |
[Dental plaque microcosm biofilm behavior on a resin composite incorporated with nano-antibacterial inorganic filler containing long-chain alkyl quaternary ammonium salt].
Topics: Anti-Bacterial Agents; Biofilms; Composite Resins; Dental Caries; Dental Plaque; Humans; Lactic Acid | 2015 |
Designing Multiagent Dental Materials for Enhanced Resistance to Biofilm Damage at the Bonded Interface.
Topics: Biofilms; Composite Resins; Dental Caries; Dental Materials; Humans; Lactic Acid; Materials Testing; | 2016 |
Candida albicans in oral biofilms could prevent caries.
Topics: Biofilms; Calcium; Candida albicans; Colony Count, Microbial; Dental Caries; Humans; Hydrogen-Ion Co | 2016 |
Chairside evaluation of pH-lowering activity and lactic acid production of dental plaque: correlation with caries experience and incidence in preschool children.
Topics: Child, Preschool; Dental Caries; Dental Caries Activity Tests; Dental Caries Susceptibility; Dental | 2008 |
Confocal laser scanning microscopic analysis of the depth of dentin caries-like lesions in primary and permanent teeth.
Topics: Bacteriological Techniques; Bicuspid; Carboxymethylcellulose Sodium; Dental Caries; Dentin; Gels; Hu | 2008 |
Impact of Streptococcus mutans on the generation of fluorescence from artificially induced enamel and dentin carious lesions in vitro.
Topics: Dental Caries; Dental Caries Activity Tests; Dental Enamel; Dentin; Fluorescence; Humans; Lactic Aci | 2008 |
Comparison of a new chairside test for caries risk assessment with established methods in children.
Topics: Chi-Square Distribution; Child; Cross-Sectional Studies; Dental Caries; Dental Caries Susceptibility | 2008 |
Self-limiting caries therapy with proteolytic agents.
Topics: Acetic Acid; Cariostatic Agents; Collagen Type I; Collagenases; Dental Caries; Dentin; Endopeptidase | 2008 |
Acid production by oral strains of Candida albicans and lactobacilli.
Topics: Acetates; Acetic Acid; Acids; Candida albicans; Child; Chromatography, Ion Exchange; Citric Acid; Co | 2009 |
Interest in a new test for caries risk in adolescents undergoing orthodontic treatment.
Topics: Adolescent; Age Factors; Buffers; Child; Cohort Studies; Colorimetry; Dental Caries; Dental Caries S | 2010 |
Cavities may soon be a thing of the past.
Topics: Animals; Dental Caries; Genetic Engineering; Humans; Lactic Acid; Rats; Streptococcus mutans | 2000 |
Relationship between fluorescence loss of QLF and depth of demineralization in an enamel erosion model.
Topics: Analysis of Variance; Animals; Cattle; Dental Caries; Dental Caries Activity Tests; Dental Enamel; D | 2009 |
Comparison of cross-sectional hardness and transverse microradiography of artificial carious enamel lesions induced by different demineralising solutions and gels.
Topics: Acetates; Acrylic Resins; Anatomy, Cross-Sectional; Animals; Apatites; Buffers; Calcium Phosphates; | 2009 |
The relation of penicillin to induced rat dental caries and oral L. acidophilus.
Topics: Animals; Bacteriology; Dental Caries; Dentistry; Lactic Acid; Lactobacillus; Lactobacillus acidophil | 1946 |
The influence of HtrA expression on the growth of Streptococcus mutans during acid stress.
Topics: Bacterial Proteins; Base Sequence; Child; Computer Systems; Dental Caries; Drug Resistance, Bacteria | 2010 |
Accuracy of a chair-side test for predicting caries risk compared with established methods. A pilot study.
Topics: Chi-Square Distribution; Child; Colony Count, Microbial; Dental Caries; Dental Caries Activity Tests | 2010 |
Diversity of Lactobacillus species in deep carious lesions of primary molars.
Topics: Bacterial Load; Calcium Hydroxide; Child; Dental Caries; Dental Cavity Preparation; Dental Pulp Capp | 2010 |
Effects of zinc and fluoride on the remineralisation of artificial carious lesions under simulated plaque fluid conditions.
Topics: Animals; Calcium; Cariostatic Agents; Cattle; Dental Caries; Dental Enamel; Dental Plaque; Durapatit | 2011 |
Dose-response effects of zinc and fluoride on caries lesion remineralization.
Topics: Animals; Apatites; Calcium Fluoride; Calcium Phosphates; Cariostatic Agents; Cattle; Citric Acid; De | 2012 |
Antibacterial nanocomposite with calcium phosphate and quaternary ammonium.
Topics: Anti-Bacterial Agents; Biofilms; Calcium Phosphates; Cariostatic Agents; Colony Count, Microbial; Co | 2012 |
Examine growth inhibition pattern and lactic acid production in Streptococcus mutans using different concentrations of xylitol produced from Candida tropicalis by fermentation.
Topics: Anti-Bacterial Agents; Candida tropicalis; Culture Media; Dental Caries; Disk Diffusion Antimicrobia | 2012 |
Effect of bamboo salt-NaF dentifrice on enamel remineralization.
Topics: Acrylic Resins; Animals; Bambusa; Calcium Phosphates; Cariogenic Agents; Cariostatic Agents; Cattle; | 2012 |
Protection of sound enamel and artificial enamel lesions against demineralisation: caries infiltrant versus adhesive.
Topics: Acrylates; Animals; Apatites; Cattle; Composite Resins; Dental Caries; Dental Enamel; Dental Enamel | 2012 |
The effects of lesion baseline characteristics and different Sr:Ca ratios in plaque fluid-like solutions on caries lesion de- and remineralization.
Topics: Analysis of Variance; Animals; Calcium Chloride; Cattle; Dental Caries; Dental Plaque; In Vitro Tech | 2012 |
Characterizing and identifying incipient carious lesions in dental enamel using micro-Raman spectroscopy.
Topics: Carbonates; Cariogenic Agents; Dental Caries; Dental Enamel; Dentin; Humans; Hydrogen-Ion Concentrat | 2013 |
Characteristics of methylcellulose acid gel lesions created in human and bovine enamel.
Topics: Animals; Cattle; Dental Caries; Dental Enamel; Dentin; Humans; Hydrogen-Ion Concentration; Lactic Ac | 2013 |
Novel dental adhesive containing antibacterial agents and calcium phosphate nanoparticles.
Topics: Ammonium Compounds; Anti-Bacterial Agents; Biofilms; Calcium Phosphates; Cell Survival; Dental Carie | 2013 |
[Comparison of demineralization of different organic acid to enamel].
Topics: Acetic Acid; Dental Caries; Dental Enamel; Dental Enamel Solubility; Dental Plaque; Formates; Humans | 1998 |
[Relationship between Streptococcus mutans, Lactobacillus spp. and lactate-producing level and nursing bottle caries].
Topics: Bottle Feeding; Child, Preschool; Dental Caries; Dental Plaque; Female; Humans; Lactic Acid; Lactoba | 2001 |
Remote glucosyltransferase-microparticle vaccine delivery induces protective immunity in the oral cavity.
Topics: Administration, Rectal; Animals; Antibodies, Bacterial; Dental Caries; Female; Glucosyltransferases; | 2003 |
[Improvement of the fluorine effect by prior acid treatment of the dental enamel].
Topics: Dental Care; Dental Caries; Dental Enamel; Fluorides; Fluorine; Humans; Lactic Acid | 1953 |
Dental caries in relation to pH on tooth surfaces. I. pH and lactate concentration in relation to the extent of the lesions in rats' teeth.
Topics: Dental Caries; Lactates; Lactic Acid | 1956 |
Dental caries in relation to pH on tooth surfaces. I. pH and lactate concentration in relation to the extent of the lesions in rats' teeth.
Topics: Dental Caries; Lactates; Lactic Acid | 1956 |
Dental caries in relation to pH on tooth surfaces. I. pH and lactate concentration in relation to the extent of the lesions in rats' teeth.
Topics: Dental Caries; Lactates; Lactic Acid | 1956 |
Dental caries in relation to pH on tooth surfaces. I. pH and lactate concentration in relation to the extent of the lesions in rats' teeth.
Topics: Dental Caries; Lactates; Lactic Acid | 1956 |
[Sugar and lactic acid content in the saliva of children with normal teeth and in multiple caries].
Topics: Carbohydrates; Child; Dental Caries; Humans; Lactic Acid; Saliva | 1951 |
Relationship between S. mutans and the autofluorescence of carious dentin.
Topics: Bicuspid; Chelating Agents; Dental Caries; Dentin; Edetic Acid; Fluorescence; Humans; Lactic Acid; M | 2004 |
Effects of sanguinaria in fluoride-containing dentifrices on the remineralisation of subsurface carious lesion in vitro.
Topics: Alkaloids; Animals; Benzophenanthridines; Cariostatic Agents; Cattle; Dental Caries; Dental Enamel; | 2005 |
STRAIN DIFFERENCES IN ORAL LACTOBACILLI AND THE RELATION TO DENTAL CARIES.
Topics: Dental Caries; Humans; Lactic Acid; Lactobacillus; Tooth | 1949 |
The effect of traditional African food mixtures on growth, pH and extracellular polysaccharide production by mutans streptococci in vitro.
Topics: Acetic Acid; Africa; Buffers; Child; Child, Preschool; Dental Caries; Dietary Carbohydrates; Ferment | 2006 |
Nature of symbiosis in oral disease.
Topics: Adaptation, Physiological; Anaerobiosis; Bacterial Physiological Phenomena; Biofilms; Dental Caries; | 2007 |
Determination of caries risk at resin composite margins.
Topics: Composite Resins; Dental Caries; Dental Caries Susceptibility; Dental Enamel; Dental Impression Mate | 2007 |
Microbial acid production (Clinpro Cario L-Pop) and dental caries in infants and children.
Topics: Biofilms; Child, Preschool; Dental Caries; Dental Caries Susceptibility; Diagnostic Tests, Routine; | 2007 |
Inhibitory effect of fluoride on tooth decalcification by citrate and lactate in vivo.
Topics: Citrates; Citric Acid; Dental Caries; Fluorides; Humans; Lactic Acid; Phosphates; Tooth; Tooth Demin | 1949 |
Is the salivary lactobacillus count a valid index of activity of dental caries?
Topics: Dental Caries; Humans; Lactic Acid; Lactobacillus; Tooth | 1949 |
Observations on Lactobacillus counts and dental caries in mental patients during insulin coma therapy.
Topics: Dental Caries; Insulin; Insulin Coma; Lactic Acid; Lactobacillus; Mental Disorders; Mentally Ill Per | 1949 |
Observations on experimental dental caries; the effect of dietary lactic acid.
Topics: Dental Caries; Diet; Humans; Lactic Acid; Tooth | 1949 |
Comparison of artificial white spots by microradiography and polarized light microscopy.
Topics: Decalcification Technique; Dental Caries; Dental Enamel; Durapatite; Etidronic Acid; Gels; Humans; H | 1984 |
Mechanism of differential staining in carious dentin.
Topics: Animals; Cattle; Collagen; Coloring Agents; Dental Caries; Dentin; Lactates; Lactic Acid; Rhodamines | 1983 |
Mineral flux of surface enamel and root surfaces in acidified gelatin gels.
Topics: Acetates; Acetic Acid; Calcium; Chemical Phenomena; Chemistry, Physical; Dental Caries; Dental Ename | 1984 |
Responses of feline intradental sensory nerves to hyperosmotic stimulation of dentin.
Topics: Action Potentials; Animals; Calcium Chloride; Cats; Dental Caries; Dentin; Female; Lactates; Lactic | 1983 |
Effect of acetic, lactic and other organic acids on the formation of artificial carious lesions.
Topics: Acetates; Acetic Acid; Acids; Dental Caries; Dental Plaque; Diffusion; Humans; Hydrogen-Ion Concentr | 1981 |
Preliminary studies on calcium lactate as an anticaries food additive.
Topics: Animals; Cariostatic Agents; Dental Caries; Food Additives; Lactates; Lactic Acid; Rats | 1982 |
The influence of manganese on carbohydrate metabolism and caries induction by Streptococcus mutans strain Ingbritt.
Topics: Animals; Carbohydrate Metabolism; Dental Caries; Hexoses; Hydrogen-Ion Concentration; Lactates; Lact | 1982 |
Effect of sodium dichloroacetate on dental caries in diabetic rats.
Topics: Acetates; Animals; Dental Caries; Diabetes Mellitus, Experimental; Dichloroacetic Acid; Lactates; La | 1982 |
Acid profiles and pH of carious dentin in active and arrested lesions.
Topics: Acetates; Adolescent; Adult; Aged; Butyrates; Butyric Acid; Caproates; Child; Dental Caries; Dental | 1994 |
An in vitro investigation of the cariogenic potential of oral streptococci.
Topics: Acetates; Acetic Acid; Calcium; Dental Caries; Durapatite; Enterococcus faecalis; Hydrogen-Ion Conce | 1994 |
Effect of fluoride incorporation into human dental enamel on its demineralization in vitro.
Topics: Buffers; Calcium; Densitometry; Dental Caries; Dental Enamel; Dental Enamel Solubility; Fluorides; H | 1993 |
Effect of sucrose concentration on the cariogenic potential of pooled plaque fluid from caries-free and caries-positive individuals.
Topics: Adolescent; Adult; Dental Caries; Dental Plaque; Humans; Lactates; Lactic Acid; Middle Aged; Strepto | 1993 |
An enzymological profile of the production of lactic acid in caries-associated plaque and in plaque formed on sound surfaces of deciduous teeth.
Topics: Child; Child, Preschool; Dental Caries; Dental Enamel; Dental Plaque; Female; Fructosediphosphates; | 1993 |
Protective effect of topically applied fluoride in relation to fluoride sensitivity of mutans streptococci.
Topics: Adaptation, Biological; Analysis of Variance; Animals; Calcium; Cattle; Dental Caries; Dental Plaque | 1993 |
Degradation and fermentation of fructo-oligosaccharides by oral streptococci.
Topics: Acetates; Acetic Acid; Dental Caries; Dental Plaque; Fermentation; Fructose; Lactates; Lactic Acid; | 1995 |
Inhibition of acid production in Streptococcus mutans R9: inhibition constants and reversibility.
Topics: Acetates; Acetic Acid; Acids; Dental Caries; Dental Plaque; Dietary Carbohydrates; Humans; Hydrogen- | 1995 |
Characterization of an unusual fluoride-resistant Streptococcus mutans isolate.
Topics: Adenosine Triphosphatases; Dental Caries; Drug Resistance; Fluorides; Glucose; Humans; Hydrogen-Ion | 1996 |
Inhibition of acid production in Streptococcus mutans R9 by formic acid.
Topics: Acetic Acid; Dental Caries; Dental Plaque; Formates; Humans; Hydrogen-Ion Concentration; Kinetics; L | 1996 |
Effects of copper, iron and fluoride co-crystallized with sugar on caries development and acid formation in deslivated rats.
Topics: Acetates; Acids; Animals; Butyrates; Cariogenic Agents; Cariostatic Agents; Colony Count, Microbial; | 1996 |
Amalgam marginal quality assessment: a comparison of seven methods.
Topics: Analysis of Variance; Bicuspid; Dental Alloys; Dental Amalgam; Dental Caries; Dental Cavity Lining; | 1997 |
Salivary and plaque acids in caries active and caries free subjects.
Topics: Acetic Acid; Adolescent; Adult; Child; Chromatography, Ion Exchange; Dental Caries; Dental Plaque; D | 1996 |
In vitro caries inhibition by polyacid-modified composite resins ('compomers').
Topics: Anti-Infective Agents, Local; Compomers; Composite Resins; Dental Caries; Dental Cavity Preparation; | 1998 |
Analysis of pH-driven disruption of oral microbial communities in vitro.
Topics: Bacteria; Chromatography, Gas; Colony Count, Microbial; Dental Caries; Dietary Carbohydrates; Fusoba | 1998 |
A preliminary study of the effect of glass-ionomer and related dental cements on the pH of lactic acid storage solutions.
Topics: Dental Caries; Dental Cements; Drug Storage; Glass Ionomer Cements; Hydrogen-Ion Concentration; Lact | 1999 |
Construction and characterization of an effector strain of Streptococcus mutans for replacement therapy of dental caries.
Topics: Animals; Dental Caries; L-Lactate Dehydrogenase; Lactic Acid; Mouth Mucosa; Open Reading Frames; Rat | 2000 |
Enamel demineralization under driving forces found in dental plaque fluid.
Topics: Cariogenic Agents; Dental Caries; Dental Enamel Solubility; Dental Plaque; Dose-Response Relationshi | 2000 |
Low-cariogenicity of trehalose as a substrate.
Topics: Animals; Cariogenic Agents; Dental Caries; Dental Plaque; Fermentation; Glucosyltransferases; Humans | 2000 |
Assessment of acid production by various human oral micro-organisms when palatinose or leucrose is utilized.
Topics: Bacteria; Chromatography, High Pressure Liquid; Dental Caries; Disaccharides; Fermentation; Humans; | 2001 |
A study of oral health condition in individuals with no oral hygiene and its association with plaque acidogenesis.
Topics: Acids, Acyclic; Bacteria; Carboxylic Acids; Dental Calculus; Dental Caries; Dental Caries Susceptibi | 2000 |
Acidogenicity and acidurance of fluoride-resistant Streptococcus sobrinus in vitro.
Topics: Acids; Cariostatic Agents; Chromatography, Gas; Dental Caries; Dental Plaque; Drug Resistance, Micro | 2000 |
[Effect of composition in plaque fluid on evaluation of individual caries risk].
Topics: Child; Dental Caries; Dental Caries Susceptibility; Dental Plaque; Electrophoresis, Capillary; Human | 2001 |
[Study of acidogenesis of dental plaque on cariogenesis using capillary electrophoresis].
Topics: Adult; Dental Caries; Dental Plaque; Electrophoresis, Capillary; Humans; Lactic Acid | 1998 |
Association of caries activity with the composition of dental plaque fluid.
Topics: Adolescent; Adult; Analysis of Variance; Calcium; Dental Caries; Dental Enamel Solubility; Dental Pl | 2001 |
Enamel microhardness after in vitro demineralization and role of different restorative materials.
Topics: Biomechanical Phenomena; Dental Caries; Dental Enamel; Humans; Lactic Acid; Models, Biological; Mola | 2002 |
Kinetics of hydroxyapatite dissolution in acetic, lactic, and phosphoric acid solutions.
Topics: Acetates; Acetic Acid; Acids; Dental Caries; Dental Enamel; Durapatite; Hydrogen-Ion Concentration; | 1992 |
Composition of pooled plaque fluid from caries-free and caries-positive individuals following sucrose exposure.
Topics: Adolescent; Adult; Calcium; Child; Dental Caries; Dental Plaque; Fluorides; Humans; Hydrogen-Ion Con | 1992 |
Noncariogenicity of erythritol as a substrate.
Topics: Actinomyces; Actinomyces viscosus; Animals; Bacterial Adhesion; Cariostatic Agents; Dental Caries; D | 1992 |
Effect of calcium in model plaque on the anticaries activity of fluoride in vitro.
Topics: Absorptiometry, Photon; Calcium; Cariostatic Agents; Dental Caries; Dental Enamel; Dental Plaque; Fl | 1992 |
Multibacterial artificial plaque. A model for studying carious process.
Topics: Dental Caries; Dental Enamel; Dental Plaque; Humans; Lactates; Lactic Acid; Streptococcus mutans; St | 1992 |
Increased resistance to artificial caries-like lesions in dentin treated with CO2 laser.
Topics: Carbon Dioxide; Densitometry; Dental Caries; Dentin; Humans; Lactates; Lactic Acid; Laser Therapy; M | 1992 |
Degradation of bovine incisor root collagen in an in vitro caries model.
Topics: Acetates; Animals; Calcium; Cattle; Collagen; Dental Caries; Hydrogen-Ion Concentration; Incisor; La | 1991 |
Permselectivity of sound and carious human dental enamel as measured by membrane potential.
Topics: Carbonic Acid; Dental Caries; Dental Enamel; Dental Enamel Permeability; Dental Plaque; Diffusion; H | 1991 |
[Uptake of fluoride into enamel and its effect on acid resistance by application of fluoride-releasing sealant--Part 2. Effect of application time and immersion time into buffer after its removal].
Topics: Animals; Buffers; Calcium; Cattle; Dental Caries; Dental Enamel; Fluorides; Hydrogen-Ion Concentrati | 1991 |
Comparison of the iodide permeability test, the surface microhardness test, and mineral dissolution of bovine enamel following acid challenge.
Topics: Animals; Calcium; Cattle; Dental Caries; Dental Enamel Permeability; Dental Enamel Solubility; Hardn | 1990 |
Mineral loss during etching of enamel lesions.
Topics: Acid Etching, Dental; Animals; Cattle; Densitometry; Dental Bonding; Dental Caries; Dental Enamel; D | 1990 |
[Cariogenicity of polydextrose and refined polydextrose as a substrate].
Topics: Animals; Bacterial Adhesion; Dental Caries; Glucans; Lactates; Lactic Acid; Rats; Streptococcus muta | 1989 |
Morphological aspects of experimental dentinal caries in rats.
Topics: Actinomyces; Animals; Dental Caries; Dentin; Diet, Cariogenic; Lactates; Lactic Acid; Lactobacillus | 1987 |
Micro-analysis of mineral saturation within enamel during lactic acid demineralization.
Topics: Calcium; Colorimetry; Dental Caries; Dental Enamel; Dental Enamel Permeability; Humans; Hydrogen; Hy | 1988 |
The effect of lactic and acetic acid on the formation of artificial caries lesions.
Topics: Acetates; Acetic Acid; Adsorption; Apatites; Dental Caries; Dental Enamel; Humans; Lactates; Lactic | 1988 |
Suitability of human, bovine, equine, and ovine tooth enamel for studies of artificial bacterial carious lesions.
Topics: Adult; Animals; Cattle; Dental Caries; Dental Enamel; Horses; Humans; Lactates; Lactic Acid; Microra | 1988 |
[Effects of calcium phosphate lactate in sweet bread spreads on experimental caries in Wistar rats].
Topics: Animals; Calcium Phosphates; Dental Caries; Diet, Cariogenic; Lactates; Lactic Acid; Rats; Rats, Inb | 1988 |
Susceptibility of natural carious lesions in enamel to an artificial caries-like attack in vitro.
Topics: Dental Caries; Dental Caries Susceptibility; Dental Enamel; Gels; Humans; In Vitro Techniques; Lacta | 1986 |
Microbiology and acid/anion profiles of enamel surface plaque from an in situ caries appliance.
Topics: Bacteria; Carboxylic Acids; Dental Caries; Dental Enamel; Dental Plaque; Equipment Design; Humans; L | 1986 |
[An analysis of the acids produced in human dental plaques].
Topics: Acetates; Adolescent; Adult; Butyrates; Carbohydrate Metabolism; Carboxylic Acids; Dental Caries; De | 1986 |
Use of synthetic polymer gels for artificial carious lesion preparation.
Topics: Acrylic Resins; Dental Caries; Dental Enamel; Gels; Hardness; Humans; Lactates; Lactic Acid; Microra | 1987 |
[The colony-forming unit and lactic acid content of human dental plaque during prolonged starvation].
Topics: Adult; Bacteria, Anaerobic; Dental Caries; Dental Plaque; Female; Food Deprivation; Humans; Lactates | 1986 |
Metabolic differences between saliva from caries-active and caries- and restoration-free children.
Topics: Child; Dental Caries; Dental Caries Susceptibility; Glycolysis; Humans; Hydrogen-Ion Concentration; | 1986 |
[Determination of sugar clearance and lactic acid in the saliva].
Topics: Dental Caries; Humans; Lactates; Lactic Acid; Saliva; Sucrose | 1987 |
[Studies on diffusion of sugars and lactic acid in human dental plaque].
Topics: Adolescent; Dental Caries; Dental Plaque; Diffusion; Female; Humans; Lactates; Lactic Acid; Male; Su | 1987 |
[Biochemical capacity of glucan-producing cariogenic Streptococci from human dental plaque with special reference to their acid-forming capacity].
Topics: Adolescent; Anaerobiosis; Child; Dental Caries; Dental Plaque; Glucans; Humans; Lactates; Lactic Aci | 1985 |
Importance of high pKA acids in cariogenic potential of plaque.
Topics: Acetates; Acetic Acid; Chemical Phenomena; Chemistry, Physical; Computers; Dental Caries; Dental Car | 1985 |
Depth of penetration of in vitro root surface lesions.
Topics: Aged; Bicuspid; Dental Caries; Dental Enamel; Gels; Humans; Lactates; Lactic Acid; Microscopy, Polar | 1985 |
Effect of calcium lactate and calcium lactophosphate on caries activity in programme-fed rats.
Topics: Animals; Calcium Phosphates; Cariostatic Agents; Dental Caries; Food Additives; Lactates; Lactic Aci | 1985 |