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Original Research

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A Comparative Study of Streptococcus Mutans and Lactobacilli in Mothers and Children With Severe Early Childhood Caries (SECC) Versus a Caries Free Group of Children and Their Corresponding Mothers

  • Haneen Al Shukairy1
  • Najlaa Alamoudi1,*,
  • Najat Farsi1
  • Abdullah Al Mushayt1
  • Ibrahim Masoud1

1,Department of Preventive Dental Sciences Faculty of DentistryKing Abdulaziz University

DOI: 10.17796/jcpd.31.2.w8555245202l6761 Vol.31,Issue 2,March 2007 pp.80-85

Published: 01 March 2007

*Corresponding Author(s): Najlaa Alamoudi E-mail: Naj_alam@yahoo.com

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Abstract

Early childhood caries (ECC) is recognized as an infectious disease. The first step in its development is primary infection by the bacterium S. mutans which has been identified as the primary etiologic factors in dental caries. Lactobacilli were also found to play a role in the progression of the disease. However, the underlying mechanism of immune response to caries is still unclear.

The purpose of this study was to assess the level of cariogenic bacteria namely S. mutans and lactobacilli in caries free children, and children with SECC and their corresponding mothers. The study also aims at correlating the children's levels to their mothers.

Sixty children and their mothers attending the dental clinic in King Abdulaziz University participated in our study. Their age ranged from 3 – 5 years. The study groups consisted of 30 children with SECC and a control group comprising of 30 caries free children.

Children together with their mothers were examined and their caries level was recorded. Stimulated saliva was collected from each participant for bacterial, immunological assessment, and Lactobacilli counts in each sample were determined.

Children with SECC had higher levels of S. mutans and Lactobacilli than caries free children. The mothers of children with SECC had a statistically higher count of Lactobacilli than caries free children's mothers. However, the difference was not statistically significant with respect to their S. mutans counts. A significant relationship exists among the mother- child pair in the SECC group with respect to S. mutans level in saliva.

Keywords

secretory IgA, Severe early childhood caries (SECC), S. mutans, saliva, cariogenic bacteria, primary molar

Cite and Share

Haneen Al Shukairy,Najlaa Alamoudi,Najat Farsi,Abdullah Al Mushayt,Ibrahim Masoud. A Comparative Study of Streptococcus Mutans and Lactobacilli in Mothers and Children With Severe Early Childhood Caries (SECC) Versus a Caries Free Group of Children and Their Corresponding Mothers. Journal of Clinical Pediatric Dentistry. 2007. 31(2);80-85.

URL:

https://www.jocpd.com/articles/10.17796/jcpd.31.2.w8555245202l6761

References

1. Caufield PW, Dasanayake A.P, Li Y, Pan Y, HSU. J, and Hardin J.M Natural history of streptococcus sanguinis in the oral cavity of infants: Evidence for a discrete window of infectivity. Infection and immunity. 60 (7) p 4018-4023, 2000.

2. Berkowitz RJ. Causes, Treatment and prevention of early childhood caries: a microbiologic perspective. J Can Dent Assoc 69(5):304-7. 2003.

3. Seow WK (1998). Biological mechanisms of early childhood caries. Community Dent Oral Epidemiol. 26(1 suppl):8-27.

4. Van Houte J. Bacterial specificity in the etiology of dental caries. Int Dent J 30:305-26, 1980.

5. Loesche WJ Role of streptococcus mutans in human dental decay. Microbiol Rev 50(4):353-80, 1986.

6. Florio FM, Klein MI, Pereira AC, Goncalves RB Time of initial acqui-sition of mutans streptococci by human infants. J Clin Pediatr Dent 28(4):303-308, 2004.

7. Caufield PW, Cuttter 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.

8. Wan AK, Seow WK, Walsh LJ, Bird PS, Tudehope DI ,Purdie DM. Association of streptococcus mutans infection and oral developmental nodules in pre-dentate infants. J. Dent Res 80:1945-1948. 2001a

9. Wan AK, Seow WK, Purdoe DM , Bird PS, Walsh LJ, Tudehope DI. Oral colonization of streptococcus mutans in six-month-old predentata infants. J Dent Res 80:2060-5. 2001b

10. Berkowitz RJ, Turner J, Green P. Maternal salivary level of streptococ-cus mutans and primary oral infection in infants. Arch Oral Biol

26(2):147-9. 1981

11. Berkowitz RJ, Jones P. Mouth-to mouth transmission of the bacterium streptococcus mutans between mother and child. Arch Oral Biol

30(4):377-9, 1985

12. Caufield PW, Wannemuehler Y, Hensen J. Familiar clustering of the streptococcus mutans cryptic plasmid strain in dental clinic population. Infect Immun 38(2):785-7, 1982.

13. Caufield PW, Ratanpridakul K, Allen DN, Cutter GR . Plasmid – con-taining strains of streptococcus mutans cluster within family and racial cohorts: implication for natural transmission. Infect immune

56(12):3216-20, 1988.

14. Kulkarni GV, Chan KH, Sandham HJ. An investigation into the use of restriction endonuclease analysis for the study of transmission of mutans streptococci. J Dent Res. 68(7):1155-1161,1989

15. Aaltonen AS, TenovuoJ, Lehtonen OP, Saksala R, Meurman O. Serum antibodies against oral streptococcus mutans in young children in rela-tion to dental caries and maternal close-contacts. Arch Oral Biol.

30:331-335. 1985

16. Van Loveren C, Buijs JF, Bokhout B, Prahl-Andersen. Ten Cate JM . Incidence of mutans streptococci and lactobacilli in oral cleft children wearing acrylic plates from shortly after birth. Oral Microbiology and Immunology 13:286-291. 1998

17. American Academy of Pediatric Dentistry Guideline (2003). Policy on early childhood caries (ECC): unique challenges and treatment options.

18. WHO (1987). Oral Health Surveys. Basic Methods. 3rd Edn. Geneva: World Health Organization.

19. Axelsson P (2000). Diagnosis and risk prediction of dental caries vol. 2; Quintessence Publishing Co. p. 91-150.

20. Berkowitz RJ, Turner J, Hughes C. Microbial characteristics of the human dental caries associated with prolonged bottle-feeding. Arch Oral Biol 29:949 – 91. 1984

21. Boue D, Armau E, Turby G. A bacteriological study of rampant caries in children. J Dent Res 66:23-28. 1987

22. Van Houte J, Gibbs G, Butera C. Oral flora of children with “nursing-bottle caries.” J Dent Res; 61:382-85. 1982

23. Matee MI, Mikx FH, Maselle SY, van Palentein Helderman WH. Mutans streptococci and lactobacilli in breast-fed children with rampant caries. Caries Res 26:183-87. 1992

24. Klock B, Krasse B. Microbial and salivary conditions in 9-12 year-old children. Scand J Dent Res; 85:56-63. 1977

25. Bretz WA, Djahjanh C, Almeida RS, Hujoel PP, Loesche WJ. Relationship of microbial and salivary parameters with dental caries in Brazilian pre-school children. Community Dent Oral Epidemiol

20:261-264. 1992

26. Thibodeau EA, O’Sullivan DM. Salivary mutans streptococci and inci-dence of caries in pre-school children. Caries Res; 29:148-53, 1995

27. Zoitopoulos L, Brailsford SR, Gelbier S, Ludford RW, Marchant SH, Beighton D. Dental caries and caries-associated microorganisms in the saliva and plaque of 3-and 4-year-old Afro-Caribbean and Caucasian children in South London. Arch Oral Biol 41:1011-8. 1996

28. Milgrom P, Riedy CA, Weinstein P, Tanner ACR, Manibusan L, Bruss J. Dental caries and its relationship to bacteria infection, hypoplasia, diet, and oral hygiene in 6-to-36-month-old children. Community Dent Oral Epidemiol; 28:295-306. 2000

29. Thorild I, Lindau-Jonson B, Twetmen S. Prevalence of salivary Streptococcus mutans in mothers and their pre-school children. Int J Pediatr Dent 12:2-7. 2002

30. Vachirarojpisan T, Shinada K, Kawaguchi Y, Laungwechakan P, Somkote T, Detsomboonrat P. Early childhood caries in children aged 6-19 months. Community Dent oral Epidemiol 32:133-42. 2004

31. Bratthall D. The global epidemiology of mutans streptococci. In: Johnson NW, editor. Risk markers for oral diseases. Vol 1. Dental caries. Cambridge: Cambridge Univ Pr; p. 287-312. 1991

32. Van Houte J. Role of microorganisms in caries etiology. J Dent Res; 73:672-81. 1994

33. Smith RE, Badner VM, Morse DE, Freeman K. Maternal risk for child hood caries in an inner city population. Community Dent Oral Epidemiol 30:176-81. 2002

34. Brambilla E, Felloni A, Gagliani M, Malerba A, Garcia-godoy F, Strohmegger L. Caries prevention during pregnancy: results of a 30-month study. J Am Dent Asso. 129:871-877. 1998

35. Soderling E, IsoKarjas P, Pieniharrinen K, Tenovuo J. Influence of maternal xylitol consumption on acquisition of mutans streptococci. J Dent Res 79:133-139. 2000

36. Köhller B, Andreen I. Influence of caries – preventive measures in mother on cariogenic bacteria and caries experience in their children. Arch Oral Biol 39:907-911. 1994

37. Gunay H, Dmoch-Bockhorn K, Gunay Y, Geurtsen W. Effect on caries experience of a long term preventive program for mothers and children starting during pregnancy. Clin Oral Invest 2:137-142. 1998

38. Gomez S, WebeA. Effectiveness of a caries preventive program in preg-nant women and new mothers on their offspring. Inter J Pediat Dent 11:117-122. 2001


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