Article Menu

Export Article

More by Authors Links

Article Data

  • Views 934
  • Dowloads 180

Original Research

Open Access

Streptococcus Mutans Strains in Mother-Child Pairs of Children with Early Childhood Caries

  • Priya Subramaniam1,*,
  • Revathy Suresh1

1Department of Pedodontics and Preventive Dentistry, The Oxford Dental College and Hospital, Hosur Road, Bommanahalli, Bangalore 560068, India

DOI: 10.17796/1053-4625-43.4.5 Vol.43,Issue 4,July 2019 pp.252-256

Published: 01 July 2019

*Corresponding Author(s): Priya Subramaniam E-mail: /

PDF (472.07 kB) View Full-text

Abstract

Objective: Dental caries is both an infectious and transmissible disease. Maternal transfer of Mutans Streptococci occurs at an early age and is important in the initiation of dental caries in children. The aim of this study was to identify certain strains of Streptococcus mutans in mother-child pairs, of children with early childhood caries. Study design: Sixty mother-child pairs of healthy children aged 18-36 months were selected. Mothers with high levels of Streptococcus mutans in their saliva and only children with ECC were included. Dental plaque samples were collected from mother-child pairs. The plaque samples were stored, transferred to the laboratory and analyzed for Streptococcus mutans strains c, f, e and k, present in motherchild pairs using Real time Polymerase Chain Reaction (PCR) technique. Data obtained was subjected to statistical analysis for level of similarity in Streptococcus mutans strains present in mother-child pairs. Results: A similar distribution of Streptococcus mutans strains c, f and k was identified in 28 mother-child pairs. Streptococcus mutans strain e was seen in 18 pairs. Conclusion: Less than 50% of mother-child pairs showed similarity in distribution of Streptococcus mutans strains.

Keywords

Early childhood caries (ECC); Streptococcus mutans; Maternal transmission

Cite and Share

Priya Subramaniam,Revathy Suresh. Streptococcus Mutans Strains in Mother-Child Pairs of Children with Early Childhood Caries. Journal of Clinical Pediatric Dentistry. 2019. 43(4);252-256.

URL:

https://www.jocpd.com/articles/10.17796/1053-4625-43.4.5

References

1. Edwardsson S, Mejàre B. Streptococcus milleri (Guthof) and Streptococcus mutans in the mouths of infants before and after tooth eruption. Arch Oral Biol ;23(9):811-4. 1978.

2. Wan AK, Seow WK, Walsh LJ, Bird P, Tudehope DL, Purdie DM. Association of Streptococcus mutans infection and oral developmental nodules in pre-dentate infants. J Dent Res; Oct;80(10):1945-8. 2001.

3. Caufield PW, Cutter GR, Dasanayake AP.Initial acquisition of mutans streptococci by infants: evidence for a discrete window of infectivity. J Dent Res ;72(1):37-45. 1993.

4. Law V, Seow WK, Townsend G. Factors influencing oral colonization of mutans streptococci in young children. Aust Dent J ;52:93-100. 2007.

5. Li Y, Caufield PW, Dasanayake AP, Wiener HW, Vermund SH. Mode of delivery and other maternal factors influence the acquisition of Streptococcus mutans in infants. J Dent Res; 84:806-11. 2005.

6. Chaffee BW, Gansky SA, Weintraub JA, Featherstone JD, Ramos-Gomez FJ. Maternal oral bacterial levels predict early childhood caries development. J Dent Res. ;93(3):238-44. 2014.

7. Li Y, Caufield PW. The fidelity of initial acquisition of mutans streptococci by infants from their mothers. J Dent Res ;74:681-5. 1995.

8. Nakano K, Nemoto H, Nomura R, Homma H, Yoshioka H, Shudo Y, Hata H, Toda K, Taniguchi K, Amano A, Ooshima T. Serotype distribution of Streptococcus mutans a pathogen of dental caries in cardiovascular specimens from Japanese patients. J Med Microbiol ;56(Pt 4):551-6. 2007.

9. Nakano K, Nomura R, Nakagawa I, Hamada S, Ooshima T. Demonstration of Streptococcus mutans with a cell wall polysaccharide specific to a new serotype, k, in the human oral cavity. J Clin Microbiol Jan;42(1):198-202. 2004.

10. Berkowitz, RJ, Jordan H, White G. The early establishment of Streptococcus mutans in the mouth of infants. Arch. Oral Biol; 20:171-4. 1975.

11. Bratthall, D. Demonstration of five serological groups of streptococcal strains resembling Streptococcus mutans. Odontol. Revy;21:143-152. 1970.

12. Perch, B., E. Kjems, T. Ravn. Biochemical and serological properties of Streptococcus mutans from various human and animal sources. Acta Pathol Microbiol Scand B Microbiol Immunol; 82:357-70. 1974.

13. Loyola-Rodriguez JP, Martinez-Martinez RE, Flores-Ferreyra BI, PatiñoMarin N, Alpuche-Solis AG, Reyes-Macias JF. Distribution of Streptococcus mutans and Streptococcus sobrinus in saliva of Mexican preschool caries-free and caries-active children by microbial and molecular (PCR) assays. J Clin Pediatr Dent ;32(2):121-6. 2008.

14. Nurelhuda NM, Al-Haroni M, Trovik TA, Bakken V. Caries experience and quantification of Streptococcus mutans and Streptococcus sobrinus in saliva of Sudanese schoolchildren. Caries Res ;44(4):402-7. 2010.

15. Rao AP, Austin RD. Serotype specific polymerase chain reaction identifies a higher prevalence of streptococcus mutans serotype k and e in a random group of children with dental caries from the Southern region of India. ; Jul;5(3):296-301. 2014.

16. Leong PM, Gussy MG, Barrow SY, de Silva-Sanigorski A, Waters E. A systematic review of risk factors during first year of life for early childhood caries. Int J Paediatr Dent. Jul;23(4):235-50. 2013.

17. Oral Health Surveys: Basic methods.5th ed. Geneva, Switzerland WHO 2013. Available from http://www.who.int/oral_health/publications/pep_ annex2formchildrentooth.pdf/en/ edited 22 August 2013. Accessed 25th Jan 2018.

18. Lindquist B, Emilson CG. Colonization of Streptococcus mutans and Streptococcus sobrinus genotypes and caries development in children to mothers harboring both species. Caries Res. Mar-Apr;38(2):95-103. 2004.

19. Kishi M, Abe A, Kishi K, Ohara-Nemoto Y, Kimura S, Yonemitsu M. Relationship of quantitative salivary levels of Streptococcus mutans and S. sobrinus in mothers to caries status and colonization of mutans streptococci in plaque in their 2.5-year-old children. Community Dent Jun;37(3):241-9. 2009.

20. Parisotto TM, Steiner-Oliveira C, Duque C, Peres RC, Rodrigues LK, Nobredos-Santos M. Relationship among microbiological composition and presence of dental plaque, sugar exposure, social factors and different stages of early childhood caries. Arch Oral Biol ;55(5):365-73. 2010.

21. Parisotto TM, Stipp R, Rodrigues LK, Mattos-Graner RO, Costa LS, NobreDos-Santos M. Can insoluble polysaccharide concentration in dental plaque, sugar exposure and cariogenic microorganisms predict early childhood caries? A follow-up study. Arch Oral Biol; 60(8): 1091-7. 2015.

22.Carletto-Korber FP, Gonzalez-lttig RE, Jimenez MG, Cornejo LS. Initial acquisition and genetic identity of streptococcus mutans of mother-child pairs. Pediatr Dent; 32 (3):205-11. 2010.

23. Alves AC, Nogueira RD, Stipp RN, Pampolini F, Moraes AB, Gonçalves RB, Höfling JF, Li Y, Mattos-Graner RO. Prospective study of potential sources of Streptococcus mutans transmission in nursery school children. J Med Microbiol ;58(Pt 4):476-81. 2009.

24. Thorild I, Lindau-Jonson B, Twetman S. Prevalence of salivary Streptococcus mutans in mothers and in their preschool children. Int J Paediatr Dent ;12(1):2-7. 2002.

25. Binks C, Duane B. Mother-to-child transmission of Streptococcus mutans. Evid Based Dent ; 16(2):39-40. 2015.

26. Hamada, S., N. Masuda, T. Ooshima, S. Sobrie, and S. Kotani. Epidemiological survey of Streptococcus mutans among Japanese children: identification and serological typing of the Jpn J Microbiol; 20(1):33-44. 1976.

27. Masuda N, Tsutsumi N, Sobue S, Hamada S. Longitudinal Survey of the Distribution of Various Serotypes of Streptococcus mutans in Infants; J Clin Microbiol;10(4): 497-502. 1979.

28. Pieralisi FJ, Rodrigues MR, Segura VG, Maciel SM, Ferreira FB, Garcia JE, Poli-Frederico RC. Genotypic Diversity of Streptococcus mutans in Caries-Free and Caries-Active Preschool Children. Int J Dent.; 824976. 2010.

29. Nakano K, Lapirattanakul J, Nomura R, et al. Streptococcus mutans clonal variation revealed by multilocus sequence typing. J Clin Microbiol. ;45:2616-25. 2007.

30. Caufield PW, Walker TM. Genetic diversity within Streptococcus mutans evident from chromosomal DNA restriction fragment polymorphisms. J Clin Microbiol. ;27:274-8. 1989.

31. Jordan C, LeBlanc DJ. Influences of orthodontic appliances on oral populations of mutans streptococci. Oral Microbiol Immunol. 2002;17:65-71.

32. Roberts MC, Riedy CA, Coldwell SE, et al. How xylitol-containing products affect cariogenic bacteria. J Am Dent Assoc.;133:435-41. 2002.

33. Gronroos L, Alaluusua S. Site-specific oral colonization of mutans streptococci detected by arbitrarily primed PCR fingerprinting. Caries Res. ;34:474-80. 2000.

34. Li Y, Caufield PW. Arbitrarily primed polymerase chain reaction fingerprinting for the genotypic identification of mutans streptococci from humans. Oral Microbiol Immunol ;13:17-22. 1998.

35. Shibata Y, Ozaki K, Seki M, Kawato T, Tanaka H, Nakano Y, Yamashita Y. Analysis of loci required for determination of serotype antigenicity in Streptococcus mutans and its clinical utilization. J Clin Microbiol;41(9):4107-12. 2003.

36. da Silva Bastos Vde A, Freitas-Fernandes LB, Fidalgo TK, Martins C, Mattos CT, de Souza IP, Maia LC. Mother-to-child transmission of Streptococcus mutans: a systematic review and meta-analysis; J Dent ;43(2):181-91. 2015.

37. Tedjosasongko U, Kozai K. Initial acquisition and transmission of mutans streptococci in children at day nursery. J Dent Child ;69:284-8. 2002.

38. Kohler B, Lundberg AB, Birkhed D, Papapanou PN. Longitudinal study of intrafamilial mutans streptococci ribotypes. Eur J Oral Sci ;111:383–389. 2003.

39. Klein MI, Florio FM, Pereira AC, Honing JF, Goncalves RB. Longitudinal study of transmission, diversity, and stability of Streptococcus mutans and Streptococcus sobrinus genotypes in Brazilian nursery children. J Clin Microbiol.;42:4620-6. 2004

40. Mitchell SC, Ruby JD, Moser S, Momeni S, Smith A, Osgood R, Litaker M, Childers N. Maternal transmission of mutans Streptococci in severeearly childhood caries. Pediatr Dent. May-Jun;31(3):193-201. 2009.

41.Napimoga MH, Höfling JF, Klein MI, Kamiya RU, Gonçalves RB. Transmission, diversity and virulence factors of Sreptococcus mutans genotypes. J Oral Sci. Jun;47(2):59-64. 2005.

Abstracted / indexed in

Science Citation Index Expanded (SciSearch) Created as SCI in 1964, Science Citation Index Expanded now indexes over 9,500 of the world’s most impactful journals across 178 scientific disciplines. More than 53 million records and 1.18 billion cited references date back from 1900 to present.

Biological Abstracts Easily discover critical journal coverage of the life sciences with Biological Abstracts, produced by the Web of Science Group, with topics ranging from botany to microbiology to pharmacology. Including BIOSIS indexing and MeSH terms, specialized indexing in Biological Abstracts helps you to discover more accurate, context-sensitive results.

Google Scholar Google Scholar is a freely accessible web search engine that indexes the full text or metadata of scholarly literature across an array of publishing formats and disciplines.

JournalSeek Genamics JournalSeek is the largest completely categorized database of freely available journal information available on the internet. The database presently contains 39226 titles. Journal information includes the description (aims and scope), journal abbreviation, journal homepage link, subject category and ISSN.

Current Contents - Clinical Medicine Current Contents - Clinical Medicine provides easy access to complete tables of contents, abstracts, bibliographic information and all other significant items in recently published issues from over 1,000 leading journals in clinical medicine.

BIOSIS Previews BIOSIS Previews is an English-language, bibliographic database service, with abstracts and citation indexing. It is part of Clarivate Analytics Web of Science suite. BIOSIS Previews indexes data from 1926 to the present.

Journal Citation Reports/Science Edition Journal Citation Reports/Science Edition aims to evaluate a journal’s value from multiple perspectives including the journal impact factor, descriptive data about a journal’s open access content as well as contributing authors, and provide readers a transparent and publisher-neutral data & statistics information about the journal.

Scopus: CiteScore 2.0 (2022) Scopus is Elsevier's abstract and citation database launched in 2004. Scopus covers nearly 36,377 titles (22,794 active titles and 13,583 Inactive titles) from approximately 11,678 publishers, of which 34,346 are peer-reviewed journals in top-level subject fields: life sciences, social sciences, physical sciences and health sciences.

Submission Turnaround Time

Conferences

Top