Епидемиолошки и етиолошки аспекти развоја каријеса зуба
Sažetak
The infectious factor is etiological in the caries development. Early colonization of S.mutans is considered as a key point; another important caries-associated microorganism is Lactobacillus, which colonizes carious lesions later. Ecological shifts in the dental plaques against the background of weakened local immunity increase their cariogenicity and lead to the caries progression. The data obtained confirm the key importance of the oral colonization resistance in initiating dental caries and its progression.
Thus, the biological status of dental plaque and the activity of cariogenic bacteria are regarded as the key mechanisms for the emergence of dental caries. Therefore, the in-depth study of oral microbial homeostasis, factors supporting its dynamic balance is extremely important for modern cariology that will greatly contribute to developing programs and recommendations for prevention of dental caries and its early detection in order to improve general health of population.
Reference
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28. Ananieva, M., Nazarchuk, O., Faustova, M., Basarab, Y., Loban, G. Pathogenicity factors of kocuria kristinae contributing to the development of peri-implant mucositis (2018) Malaysian Journal of Medicine and Health Sciences, 14 (3), pp. 34-38.
29. Faustova MO, Ananieva MM, Basarab YO, Dobrobolska OV, Vovk IM, Loban' GA. Bacterial factors of cariogenicity (literature review). Wiadomosci Lekarskie. 2018;71(2 pt 2):378-382.
30. Takahashi N, Nyvad B: Caries ecology revisited: microbial dynamics and the caries process. Caries Research. 2008;42:409-418.
31. Devine DA, Marsh PD, Meade J: Modulation of host responses by oral commensal bacteria. Journal of Oral Microbiology. 2015;7:26941.
32. Petrushanko, TA., Tchereda VV, Loban GA. [The screening diagnostic of micro ecological disorders of oral cavity]. Klinicheskaiia Laboratornaiia Diagnostika. 2014;(6):48-50.
33. Faustova, M.O., Ananieva, M.M., Basarab, Y.O., Loban', G.A. Neutrophil bactericidal activity through the stages of placement of different dental implants depending on their chemical composition. Wiadomosci lekarskie. 2017:70 (5):921-924.
2. Petrushanko TA, Chereda VV, Loban' GA. The relationship between colonization resistance of the oral cavity and individual-typological characteristics of personality: dental aspects. Wiadomosci Lekarskie 2017;70(4):754-757.
3. Rugg-Gunn A. Dental caries: strategies to control this preventable disease. Acta Medica Academica 2013;42(2):117-30.
4. Davies GM, Neville J, Jones K, White S. Why are caries levels reducing in five-year-olds in England? British Dental Journal 2017;223(7):515-519.
5. Casamassimo PS, Thikkurissy S, Edelstein BL, Maiorini E. Beyond the dmft: the human and economic cost of early childhood caries. Journal of the American Dental Association 2009;140:650-657.
6. Kato H, Tanaka K, Shimizu K et al. Parental occupations, educational levels, and income and prevalence of dental caries in 3-year-old Japanese children. Environmental Health and Preventive Medicine 2017;22(1):80.
7. Sheiham A, James WP. A new understanding of the relationship between sugars, dental caries and fluoride use: implications for limits on sugars consumption. Public Health Nutrition 2014;17(10):2176-84.
8. Sun HB, Zhang W, Zhou XB. Risk Factors associated with Early Childhood Caries. The Chinese Journal of Dental Research 2017;20(2):97-104.
9. Drachev SN, Brenn T, Trovik TA. Oral Health-Related Quality of Life in Young Adults: A Survey of Russian Undergraduate Students. International Journal of Environmental Research and Public Health 2018;15(4). pii: E719.
10. Rosier BT, Marsh PD, Mira A. Resilience of the Oral Microbiota in Health: Mechanisms That Prevent Dysbiosis. Journal of Dental Research 2018; 97(4):371-380.
11. Zaura E, Keijser BJ, Huse SM, Crielaard W. Defining the healthy “core microbiome” of oral microbial communities. BMC Microbiology 2009;9:259.
12. Zaura E, Nicu EA, Krom BP, Keijser BJF. Acquiring and maintaining a normal oral microbiome: current perspective. Frontiers in Cellular and Infection Microbiology 2014;4:85.
13. Petrushanko TA, Chereda VV, Loban' GA. [Role of oral cavity colonization resistance in dental caries development]. Stomatologiia. 2013;92(1):43-5.
14. Tanner ACR, Kressirer CA, Rothmiller S, Johansson I, Chalmers NI. The Caries Microbiome: Implications for Reversing Dysbiosis. Advanses in Dental Research 2018;29(1):78-85.
15. Takahashi N, Nyvad B. The role of bacteria in the caries process: ecological perspectives. Journal of dental research. 2011;90(3):294–303.
16. Mitrakul K, Asvanund Y, Vongsavan K. Prevalence of five biofilm-related oral streptococci species from plaque. The Journal of clinical pediatric dentistry. 2011;36(2):161–6.
17. Mitrakul K, Vongsavan K, Suratanachaikul P. Prevalence of Streptococcus mutans and Lactobacillus fermentum and their association with caries and dietary habits in preschool Thai children. European archives of paediatric dentistry: official journal of the European Academy of Paediatric Dentistry. 2013;14(2):83–7.
18. Aitken-Saavedra J, Rojas-Alcayaga G, Maturana-Ramirez A et al. Salivary gland dysfunction markers in type 2 diabetes mellitus patients. Journal of clinical and experimental dentistry. 2015;7(4):e501–5.
19. Leite RS, Marlow NM, Fernandes JK. Oral health and type 2 diabetes. The American journal of the medical sciences. 2013;345(4):271–3.
20. Negrato CA, Tarzia O. Buccal alterations in diabetes mellitus. Diabetology and Metabolic Syndrome. 2010;2:3
21. Rai K, Hegde AM, Kamath A, Shetty S. Dental caries and salivary alterations in Type I Diabetes. The Journal of clinical pediatric dentistry. 2011;36(2):181–4.
22. Miko S, Ambrus SJ, Sahafian S, Dinya E, Tamas G, Albrecht MG. Dental caries and adolescents with type 1 diabetes. British Dental Journal. 2010;208(6):E12
23. Saes Busato IM, Bittencourt MS, Machado MAN, Gregio AMT, Azevedo-Alanis LR. Association between metabolic control and oral health in adolescents with type 1 diabetes mellitus. Oral Surgery, Oral Medicine Oral Pathology Oral Radiology and Endodontics. 2010;109(3):e51–6.
24. Tagelsir A, Cauwels R, van Aken S, Vanobbergen J, Martens LC. Dental caries and dental care level (restorative index) in children with diabetes mellitus type 1. International Journal of Paediatric Dentistry. 2011;21(1):13–22.
25. Akpata ES, Alomari Q, Mojiminiyi OA, Al-Sanae H. Caries experience among children with type 1 diabetes in Kuwait. Pediatric dentistry. 2012;34(7):468–72.
26. Lai S, Cagetti MG, Cocco F, Cossellu D, Meloni G, Campus G, Lingström P. Evaluation of the difference in caries experience in diabetic and non-diabetic children-A case control study. PLoS One. 2017 Nov 30;12(11):e0188451
27. Ananieva MM, Faustova MO, Basarab IO, Loban' GA. Kocuria rosea, Kocuria kristinae, Leuconostoc mesenteroides as caries-causing representatives of oral microflora. Wiadomosci Lekarskie . 2017;70(2):296-8.
28. Ananieva, M., Nazarchuk, O., Faustova, M., Basarab, Y., Loban, G. Pathogenicity factors of kocuria kristinae contributing to the development of peri-implant mucositis (2018) Malaysian Journal of Medicine and Health Sciences, 14 (3), pp. 34-38.
29. Faustova MO, Ananieva MM, Basarab YO, Dobrobolska OV, Vovk IM, Loban' GA. Bacterial factors of cariogenicity (literature review). Wiadomosci Lekarskie. 2018;71(2 pt 2):378-382.
30. Takahashi N, Nyvad B: Caries ecology revisited: microbial dynamics and the caries process. Caries Research. 2008;42:409-418.
31. Devine DA, Marsh PD, Meade J: Modulation of host responses by oral commensal bacteria. Journal of Oral Microbiology. 2015;7:26941.
32. Petrushanko, TA., Tchereda VV, Loban GA. [The screening diagnostic of micro ecological disorders of oral cavity]. Klinicheskaiia Laboratornaiia Diagnostika. 2014;(6):48-50.
33. Faustova, M.O., Ananieva, M.M., Basarab, Y.O., Loban', G.A. Neutrophil bactericidal activity through the stages of placement of different dental implants depending on their chemical composition. Wiadomosci lekarskie. 2017:70 (5):921-924.
Objavljeno
2025/12/21
Broj časopisa
Rubrika
Pregledni rad / Review article