Periodontics. Fernando Suarez
1997;13:91–120.
29. Page RC, Ammons WF, Schectman LR, Dillingham LA. Collagen fibre bundles of the normal marginal gingiva in the marmoset. Arch Oral Biol 1974;19:1039–1043.
30. Cohen B. Pathology of the interdental tissues. Dent Pract 1959;9:167–173.
31. Cohen DW. Pathogenesis of Periodontal Disease and Its Treatment. Washington, DC: Walter Reed Army Medical Center, 1962.
32. Gargiulo AW, Wentz FM, Orban B. Dimensions and relations of the dentogingival junction in humans. J Periodontol 1961;32:261–267.
33. Vacek JS, Gher ME, Assad DA, Richardson AC, Giambarresi LI. The dimensions of the human dentogingival junction. Int J Periodontics Restorative Dent 1994;14:154–165.
34. Schmidt JC, Sahrmann P, Weiger R, Schmidlin PR, Walter C. Biologic width dimensions: A systematic review. J Clin Periodontol 2013;40:493–504.
35. Berglundh T, Lindhe J, Ericsson I, Marinello CP, Liljenberg B, Thomsen P. The soft tissue barrier at implants and teeth. Clin Oral Implants Res 1991;2:81–90.
36. Moon IS, Berglundh T, Abrahamsson I, Linder E, Lindhe J. The barrier between the keratinized mucosa and the dental implant. An experimental study in the dog. J Clin Periodontol 1999;26:658–663.
37. Berglundh T, Lindhe J, Jonsson K, Ericsson I. The topography of the vascular systems in the periodontal and peri-implant tissues in the dog. J Clin Periodontol 1994;21:189–193.
DEFINITIONS AND TERMINOLOGY
Clinical attachment level: The distance from the cementoenamel junction (CEJ) to the tip of a periodontal probe during periodontal diagnostic probing. The health of the attachment apparatus can affect the measurement.1
Furcation: The anatomical area of a multirooted tooth where the roots diverge.1
Furcation involvement: Pathologic resorption of bone within a furcation. The degree of interradicular bony destruction of a multirooted tooth. It is characterized by factors such as root trunk length, root concavities, and the extent of root separation.2
Recession: The migration of the marginal soft tissue to a point apical to the CEJ of a tooth or the platform of a dental implant.1
A thorough and comprehensive clinical and radiographic examination is the critical first step for establishing a proper periodontal diagnosis before a treatment plan can be developed. The objective of this chapter is to review the main components of a periodontal examination and interpretation of these parameters to aid in developing a periodontal diagnosis. The second part of this chapter is an overview of the different classifications for periodontal diseases and conditions that have been proposed and developed over the years.
Clinical Examination
To determine a proper periodontal diagnosis, clinicians should perform a periodontal examination that includes but is not limited to the following parameters2,3:
Probing depth (PD)
Gingival recession
Clinical attachment level (CAL)
Width of keratinized gingiva (KG) and attached gingiva (AG)
Signs of gingival inflammation (ie, bleeding on probing [BOP], suppuration, gingival color and texture)
Tooth mobility
Degree of furcation involvement
Extent, distribution, and pattern of radiographic bone loss
Patient’s medical and dental history3
PROBING DEPTH
The measurement of PDs is considered to be one of the most important parameters of the periodontal examination because it provides an overall assessment of the periodontal pockets, which are usually considered as a critical sign for the establishment of a diagnosis. In addition, pockets are also the major habitats for periodontal pathogens.3 Currently, the most widely used instrument to obtain PDs in clinical practice is the conventional or manual probe. In 1936, periodontist Charles H. M. Williams created the first periodontal probe, and his invention—the Williams periodontal probe—has been the prototype or benchmark for all manual probes.4 Different types of conventional periodontal probes have been developed over the years and utilized for different indications. Box 2-1 summarizes the common types of conventional probes used in the clinic and their characteristics and indications.4
BOX 2-1 Common types of periodontal probes
Williams probe
The graduations on this probe are 1-, 2-, 3-, 5-, 7-, 8-, 9-, and 10-mm. The 4- and 6-mm markings are absent to improve visibility and avoid confusion in reading the markings.
Merritt B probe
The graduations and markings on this probe are the same as Williams probe.
Goldman-Fox probe
This probe has a flattened tip. The graduations and markings on this probe are the same as Williams probe; however, the flat tip end might preclude easy access into tight or narrow pockets.
UNC 15 probe
The graduations on this probe are 1-, 2-, 3-, 4-, 5-, 6-, 7-, 8-, 9-, 10-, 11-, 12-, 13-, 14-, and 15-mm. This probe is color-coded at every millimeter demarcation, and it is suitable for deeper pockets (ie, > 10 mm).
Marquis color-coded probe
The graduations on this probe are 3-, 6-, 9-, and 12-mm. Color markings are darker at 3–6 mm and 9–12 mm. The main disadvantage of this probe is its accuracy; the measurements are usually estimated between color markings.
Michigan O probe
The graduations on this probe are 3-, 6-, and 8-mm and are color-coded. This probe might not be suitable for deeper pockets (ie, > 8 mm), and the measurements are also estimated between color markings.
CPITN probe
The graduations on this probe are 3.5-, 5.5-, 8.5-, and 11.5-mm. Markings are a darker color at 3.5–5.5 mm and 8.5–11.5 mm. This probe is particularly useful for screening and monitoring patients or for epidemiologic research.
UNC, University of North Carolina; CPITN, community periodontal index of treatment needs.
Conventional probes are easily operated and inexpensive; therefore, these are the most commonly used probe system in dental clinics. However, conventional probes also present with several disadvantages4:
The pressure applied cannot be standardized.
Assistants are often needed to transfer measurements