Periodontal fiber explained

Periodontal ligament
Latin:fibra periodontalis
Acronym:PDL
Precursor:Dental follicle

The periodontal ligament, commonly abbreviated as the PDL, are a group of specialized connective tissue fibers that essentially attach a tooth to the alveolar bone within which they sit.[1] It inserts into root cementum on one side and onto alveolar bone on the other.

Structure

The PDL consists of principal fibers, loose connective tissue, blast and clast cells, oxytalan fibers and cell rest of Malassez.[2]

Alveolodental ligament

The main principal fiber group is the alveolodental ligament, which consists of five fiber subgroups: alveolar crest, horizontal, oblique, apical, and interradicular on multirooted teeth. Principal fibers other than the alveolodental ligament are the transseptal fibers.

All these fibers help the tooth withstand the naturally substantial compressive forces that occur during chewing and remain embedded in the bone. The ends of the principal fibers that are within either cementum or alveolar bone proper are considered Sharpey fibers.

Transseptal fibers

Transseptal fibers (H) extend interproximally over the alveolar bone crest and are embedded in the cementum of adjacent teeth; they form an interdental ligament. These fibers keep all the teeth aligned. These fibers may be considered as belonging to the gingival tissue because they do not have an osseous attachment.[3] .These fibers are consistent and are reconstructed even after the destruction of alveolar bone.

Loose connective tissue

Loose connective tissue contains fibers, extracellular matrix, cells, nerves and blood vessels. The extracellular compartment consists of Type 1, 3, and 5 collagen fibers bundles embedded in intercellular substance. The PDL collagen fibers are categorized according to their orientation and location along the tooth. The cells include fibroblast, defence cells and undifferentiated mesenchymal cells.

Cell rest of Malassez

These groups of epithelial cells become located in the mature PDL after the disintegration of Hertwig epithelial root sheath during the formation of the root. They form a plexus that surrounds the tooth. Cell rests of Malassez might proliferate during inflammation which may lead to radicular cyst formation in later life.

Oxytalan fibers

Oxytalan fibers are unique to the PDL and are elastic in nature. It inserts into cementum and runs in two directions: parallel to root surface and oblique to root surface. The function is thought to maintain the patency of blood vessels during occlusal loading. Further research is needed to determine the function of oxytalan fibers.[4]

Composition

The PDL substance has been estimated to be 70% water, which is thought to have a significant effect on the tooth's ability to withstand stress loads. The completeness and vitality of the PDL are essential for the functioning of the tooth.

The PDL ranges in width from 0.15 to 0.38mm with its thinnest part located in the middle third of the root. The width progressively decreases with age.

The PDL is a part of the periodontium that provides for the attachment of the teeth to the surrounding alveolar bone by way of the cementum.

The PDL appears as the periodontal space of 0.4 to 1.5 mm on radiographs, a radiolucent area between the radiopaque lamina dura of the alveolar bone proper and the radiopaque cementum.

Development

PDL cells are one of the many cells derived from the dental follicle and this occurs after crown formation is completed and when the roots start developing. These cells will remodel the dental follicle to form the PDL.[5] Formation of PDL will start at the cementoenamel junction and proceeds in an apical direction.[6]

Effects of mechanical forces

Movement of teeth is determined by two factors: deposition of bone on the tension side and resorption of the bone on the compression side of the periodontal ligament (PDL). During this movement, bone remodelling is initiated by the PDL in which forces are transmitted from the tooth to the alveolar bone. Fibroblasts of the PDL will react to mechanical stress, therefore affecting osteoblastogenesis and osteoclastogenesis of the cells. When mechanical stimuli are introduced to the cells, osteocytes in the PDL will differentiate into osteoclasts which will then reform and remodel the bone structure in the affected area. For example, orthodontic treatment involves application of a mechanical force on to the teeth to align them and this is done through this complex combination of physical and cellular processes.[7]

Function

Functions of PDL are supportive, sensory, nutritive, and remodelling.[8]

Support

The PDL is a part of the periodontium that provides for the attachment of the teeth to the surrounding alveolar bone by way of the cementum. PDL fibres also provide a role in load transfer between the teeth and alveolar bone. (PDL fibers absorb and transmit forces between teeth and alveolar bone. It acts as an effective support during the masticatory function.)[9]

Sensory

PDL is heavily innervated; it involves mechanoreception, nociception and reflexes. Periodontal mechanoreceptors are present in PDL. They will transmit information about the stimulated tooth, direction and amplitude of forces.[10]

Nutritive

It maintains the vitality of the surrounding cells. (PDL is heavily anastomosed). There are three principal sources of blood vessels which are apical vessels, perforating vessels and gingival vessels. Apical vessels originate from vessels that supply the pulp. Perforating vessels originate from lamina dura and the vessels perforate the socket wall (cribriform plate). Gingival vessels are derived from the gingival tissue. Outer layers of blood supply in PDL may help in mechanical suspension and support of the tooth while inner layers of blood vessels supply surrounding PDL tissues.[11]

Remodeling

There are progenitor cells in the periodontal ligament that can differentiate into osteoblasts for the physiological maintenance of alveolar bone and, most likely, for its repair as well.

Clinical significance

Injury

Disease

Effect of tobacco smoking and nicotine

There is a relationship between smoking tobacco and periodontal disease, wound healing and oral cancers.[15]

Nicotine, the major pharmacologically active ingredient in tobacco smoke, lessens a host's ability to defend against bacterial invasion induced by plaque. It is also the ingredient responsible for addiction.[16]

Tobacco smoking impairs phagocytic and chemotactic activities of leukocytes[17] and impedes wound healing,[18] specifically by affecting gingival blood flow.[19] [20]

Cigarette smokers are more likely to experience destruction of the alveolar bone and periodontal ligament and are at a higher risk of developing periodontal disease.[21] [22]

Nicotine and lipopolysaccharides synergistically induce the production of nitric oxide (NO) and PGE2, and increase inducible nitric oxide synthase (iNOS) and COX-2 expression in human periodontal ligament (hPDL) cells.

At the cellular level, nicotine reduces the proliferation of red blood cells, macrophages, and fibroblasts and increases platelet adhesiveness.

Macroscopically, this affects healing and tissue perfusion due to micro clot formation in the blood vessels.[23] [24] Nicotine also has a sympathomimetic action, stimulating epinephrine and norepinephrine release, which causes vasoconstriction and limits tissue perfusion. Nicotine jeopardises bone formation by inhibiting neovascularization and osteoblastic differentiation.[25] [26] [27] [28] [29]

Ankylosis

Ankylosis is a condition where the cementum of the tooth's root fuses with the bone that is around the tooth. The osseous tissue replaces the periodontal ligament which causes the tooth to be fixed and cannot undergo eruptive change. Ankylosis usually occurs in primary molars; however, it can also take place in other primary teeth, as well as secondary dentition. Ankylosis is common in the anterior tooth after trauma and can be referred to as replacement resorption. In this process PDL cells are destroyed and as a result the cells of the alveolar bone will perform most of the healing. Radiographic examination of a patient with ankylosis may also reveal a loss of the PDL and bony bridging.

Effect of nutrition

Nutritional status of an individual can be a crucial factor in the progression and healing of periodontal tissues. The relationship between oral health and systemic health has become an increasingly important subject. Studies have suggested that vitamins D and C in particular have a certain grade of relationship with periodontal health. However, it is important to note that supplementation of vitamins is not enough to reverse the periodontium to a healthy state and that further research is needed to confirm theories.

For example, scurvy is a disease resulting from a severe deficiency of vitamin C (ascorbic acid). Vitamin C is essential for the synthesis of collagen fibers.

See also

External links

Notes and References

  1. Book: Wolf HF, Rateitschak KH . Periodontology. 21 June 2011. 2005. Thieme. 978-0-86577-902-0. 12–.
  2. Web site: Listgarten MA . . Principal fibers of the periodontal ligament . University of Pennsylvania and Temple University . It is the different composition of collagens which give various ECM functions and abilities. There is a mixture of thick and thin fibres in the PDL. It is important to note that, in reality, the fibres are not as defined as these classifications. . https://web.archive.org/web/20120620155346/http://www.dental.pitt.edu/informatics/periohistology/en/gu0404.htm . 20 June 2012 .
  3. Book: Naci A . Ten Cate's Oral Histology . Elsevier . 2013 . 274 . 978-0-323-07846-7 .
  4. Strydom H, Maltha JC, Kuijpers-Jagtman AM, Von den Hoff JW . The oxytalan fibre network in the periodontium and its possible mechanical function . Archives of Oral Biology . 57 . 8 . 1003–11 . August 2012 . 22784380 . 10.1016/j.archoralbio.2012.06.003 .
  5. Yao S, Pan F, Prpic V, Wise GE . Differentiation of stem cells in the dental follicle . Journal of Dental Research . 87 . 8 . 767–71 . August 2008 . 18650550 . 2553250 . 10.1177/154405910808700801 .
  6. de Jong T, Bakker AD, Everts V, Smit TH . The intricate anatomy of the periodontal ligament and its development: Lessons for periodontal regeneration . Journal of Periodontal Research . 52 . 6 . 965–974 . December 2017 . 28635007 . 10.1111/jre.12477 . 38159994 .
  7. Li M, Zhang C, Yang Y . Effects of mechanical forces on osteogenesis and osteoclastogenesis in human periodontal ligament fibroblasts: A systematic review of in vitro studies . Bone & Joint Research . 8 . 1 . 19–31 . January 2019 . 30800296 . 6359886 . 10.1302/2046-3758.81.BJR-2018-0060.R1 .
  8. Web site: Listgarten MA . Periodontal ligament . University of Pennsylvania and Temple University . https://web.archive.org/web/20100616021315/http://www.dental.pitt.edu/informatics/periohistology/en/gu0401.htm . 16 June 2010 .
  9. McCormack SW, Witzel U, Watson PJ, Fagan MJ, Gröning F . The biomechanical function of periodontal ligament fibres in orthodontic tooth movement . PLOS ONE . 9 . 7 . e102387 . 2014 . 25036099 . 4103804 . 10.1371/journal.pone.0102387 . 2014PLoSO...9j2387M . free .
  10. Trulsson M . Sensory-motor function of human periodontal mechanoreceptors . Journal of Oral Rehabilitation . 33 . 4 . 262–73 . April 2006 . 16629881 . 10.1111/j.1365-2842.2006.01629.x . free .
  11. Institute of Anatomy, University of Veterinary Medicine Hannover, Bischofsholer Damm 15, D-30173 Hannover, Germany
  12. Zadik Y . Algorithm of first-aid management of dental trauma for medics and corpsmen . Dental Traumatology . 24 . 6 . 698–701 . December 2008 . 19021668 . 10.1111/j.1600-9657.2008.00649.x .
  13. Layug ML, Barrett EJ, Kenny DJ . Interim storage of avulsed permanent teeth . Journal . 64 . 5 . 357–63, 365–9 . May 1998 . 9648418 .
  14. Kim JH, Koo KT, Capetillo J, Kim JJ, Yoo JM, Ben Amara H, Park JC, Schwarz F, Wikesjö UM . 6 . Periodontal and endodontic pathology delays extraction socket healing in a canine model . Journal of Periodontal & Implant Science . 47 . 3 . 143–153 . June 2017 . 28680710 . 5494309 . 10.5051/jpis.2017.47.3.143 .
  15. World Health Organization Monograph on Tobacco Cessation and Oral Health Integration, Geneva (2017)
  16. Whiteford L . Nicotine, CO and HCN: the detrimental effects of smoking on wound healing . British Journal of Community Nursing . 8 . 12 . S22-6 . December 2003 . 14700008 . 10.12968/bjcn.2003.8.sup6.12554 .
  17. Tomar SL, Asma S . Smoking-attributable periodontitis in the United States: findings from NHANES III. National Health and Nutrition Examination Survey . Journal of Periodontology . 71 . 5 . 743–51 . May 2000 . 10872955 . 10.1902/jop.2000.71.5.743 .
  18. Genco RJ, Borgnakke WS . Risk factors for periodontal disease . Periodontology 2000 . 62 . 1 . 59–94 . June 2013 . 23574464 . 10.1111/j.1600-0757.2012.00457.x .
  19. Leite FR, Nascimento GG, Scheutz F, López R . Effect of Smoking on Periodontitis: A Systematic Review and Meta-regression . American Journal of Preventive Medicine . 54 . 6 . 831–841 . June 2018 . 29656920 . 10.1016/j.amepre.2018.02.014 . 4893172 .
  20. Qandil R, Sandhu HS, Matthews DC . Tobacco smoking and periodontal diseases . Journal (Canadian Dental Association) . 63 . 3 . 187–92, 194–5 . March 1997 . 9086680 .
  21. Morozumi T, Kubota T, Sato T, Okuda K, Yoshie H . Smoking cessation increases gingival blood flow and gingival crevicular fluid . Journal of Clinical Periodontology . 31 . 4 . 267–72 . April 2004 . 15016254 . 10.1111/j.1600-051x.2004.00476.x .
  22. Johnson GK, Todd GL, Johnson WT, Fung YK, Dubois LM . Effects of topical and systemic nicotine on gingival blood flow in dogs . Journal of Dental Research . 70 . 5 . 906–9 . May 1991 . 2022772 . 10.1177/00220345910700050801 . 28627546 .
  23. Ciftçi O, Günday M, Calişkan M, Güllü H, Güven A, Müderrisoğlu H . Light cigarette smoking and vascular function . Acta Cardiologica . 68 . 3 . 255–61 . June 2013 . 23882870 . 10.1080/ac.68.3.2983419 . 42726406 .
  24. Tomar SL, Asma S . Smoking-attributable periodontitis in the United States: findings from NHANES III. National Health and Nutrition Examination Survey . Journal of Periodontology . 71 . 5 . 743–51 . May 2000 . 10872955 . 10.1902/jop.2000.71.5.743 .
  25. Pi SH, Jeong GS, Oh HW, Kim YS, Pae HO, Chung HT, Lee SK, Kim EC . 6 . Heme oxygenase-1 mediates nicotine- and lipopolysaccharide-induced expression of cyclooxygenase-2 and inducible nitric oxide synthase in human periodontal ligament cells . Journal of Periodontal Research . 45 . 2 . 177–83 . April 2010 . 20470258 . 10.1111/j.1600-0765.2009.01215.x .
  26. Jones JK, Triplett RG . The relationship of cigarette smoking to impaired intraoral wound healing: a review of evidence and implications for patient care . Journal of Oral and Maxillofacial Surgery . 50 . 3 . 237–9; discussion 239–40 . March 1992 . 1542066 . 10.1016/0278-2391(92)90318-t .
  27. Saito Y, Sato S, Oginuma T, Saito Y, Arai Y, Ito K . Effects of nicotine on guided bone augmentation in rat calvarium . Clinical Oral Implants Research . 24 . 5 . 531–5 . May 2013 . 22276738 . 10.1111/j.1600-0501.2011.02416.x .
  28. Donigan JA, Fredericks DC, Nepola JV, Smucker JD . The effect of transdermal nicotine on fracture healing in a rabbit model . Journal of Orthopaedic Trauma . 26 . 12 . 724–7 . December 2012 . 22955337 . 10.1097/bot.0b013e318270466f . 29873064 .
  29. Glowacki J, Schulten AJ, Perrott D, Kaban LB . Nicotine impairs distraction osteogenesis in the rat mandible . International Journal of Oral and Maxillofacial Surgery . 37 . 2 . 156–61 . February 2008 . 17983728 . 10.1016/j.ijom.2007.08.001 .