Periodontal Bone Defects Will be Detected and Measured by 2 Techniques CBCT and Intraoral Digital Radiography to Compare the Accuracy of These Techniques Clinical Trial
Official title:
Cone Beam Computed Tomography Versus Intraoral Digital Radiography in Detection and Measurements of Simulated Periodontal Bone Defects Diagnostic Accuracy Study
The selection of a regenerative approach is primarily based on the configuration of the
intrabony defect and esthetic risk of treatment. Accurate diagnosis of periodontal bone
defects, such as vertical bone defects or furcation involvements, is a challenge for dental
clinicians. A deficiency in comprehensive diagnosis may result in: 1) compromised prognosis
of teeth; 2) changes in treatment plan; 3) unnecessary treatment; 4) longer treatment time;
and 5) unanticipated treatment costs.
Thus, it is very important to have access to accurate diagnostic tools that can aid
clinicians in cultivating an appropriate treatment choice. Periodontal assessments utilizing
both clinical and radiographic examinations allow for the establishment of an accurate
diagnosis as well as subsequent treatment choices.
Radiography plays an important role in periodontal diagnosis mainly because radiographs can
reveal the amount and type of damage caused to the alveolar bone.
Digital imaging technique has created challenging opportunities for dental radiographic
diagnosis. Digora was the first digital system for dental radiography based on a
photostimulable phosphor technology.
E9ickholz et al. at 1999 compared linear measurements of interproximal bone loss on digitized
radiographic images after application of different filters to the gold standard of
intrasurgical measurements they concluded that all radiographic assessments on the digitized
images came close to the intasurgical gold standard.
2D technologies do not allow for measurement of the bucco-lingual (B-L) width of the defect.
Only the vertical height and the mesio-distal (M-D) width of the defect can be measured with
2D images.
Use of 3D volumetric images and 2D images in artificial bone defects have shown that CBCT has
a sensitivity of 80% to 100% in detection and classification of bone defects, while intraoral
radiographs present a sensitivity of 63% to 67%.
When compared with periapical and panoramic images, the CBCT has also shown an absence of
distortion and overlapping, and the dimensions of the images that it presents were compatible
with the actual size of the individual.
A few studies have been published comparing CBCT with digital radiography for the detection
and measurements of periodontal bone defects.
Periodontal disease is caused by an imbalance between bone formation and resorption, leading
to an ultimate reduction in bone height. Detection of periodontal disease is important in the
prevention of tooth loss. The detection and accurate assessment of the location, extent and
configuration of the endosseous defect is important for the determination of the tooth
prognosis, the treatment plan and the maintenance procedures.
Regenerative therapies for both intrabony and furcation defects are viable options, but early
management of these defects offers the greatest potential for periodontal health. Intrabony
defect morphology as well as degree of furcation involvement may affect overall regenerative
outcomes and/or optimal treatment strategies.
Radiographic bone loss is also useful for assigning descriptors to indicate severity of
periodontitis: <1/3 bone loss = mild, 1/3 to ½ bone loss = moderate, and >½ bone loss =
severe. Classification of bony defects given by Papapanou et al. 2000 was used to
differentiate bone defects into: Suprabony defects (SB), Infrabony defects (IB),
Interradicular defects (IR).For classifying the intrabony defects (IT), the investigators
used classification system by Goldman and Cohen 1958 which classified the IT defects into: 1
wall, 2 wall , 3 wall and Combined bone defects (CB). Other bone defects (OB) were classified
by their topography as:Bulbous bone contour (BB), Reversed architecture (RA), Dehiscence
(DH).
The potentially existing radiological furcation involvement was examined by identifying the
furcation upper boundary and furcation lower boundary and was classified as Subclass A, B,
and C according to the classification system by Tarnow and Fletcher 1984, where he added the
vertical component to the diagnosis of furcation involvement. Subclass based on the vertical
bone resorption from the furcation fornix was added.
- Subclass A: Denotes furcation involvements with vertical bone loss of 3 mm or less.
- Subclass B: Denotes furcation involvements with vertical bone loss from 4 to 6 mm.
- Subclass C: Presents with bone loss from the fornix of 7 mm or more.
- The SB, IB, and OB defects were considered as absolute defects while IR defects
were considered as relative defects because IR defects do not depict a particular
bone lesion or defect rather they represent the stage in progress of periodontitis,
i.e., once the periodontal disease progresses or its severity increases, it is
bound to erode the bone between the multirooted teeth and involve the furcation.
Digital radiography is changing the diagnosis and treatment of dental diseases by
incorporating computer technology into the field of dentistry. digital radiography have
several advantages over film radiography, including immediate image production with
solid-state devices; interactive display on a monitor with the ability to enhance image
features and make direct linear and densitometric measurements; integrated storage; fast
communication of images; lower contamination of the environment; security mechanisms to
identify original images; ability to tag information such as a patient identifier, date of
exposure and other relevant details; interoperability of the Digital Imaging and
Communications in Medicine (DICOM) file format, which enables practitioners with different
equipment and software to view and enhance the same images.
Furthermore, digital radiography offers a plethora of technical innovations to dentistry and
is sure to significantly influence the arts of diagnosis, monitoring, research, as well as
the treatment of dental diseases.
Cone beam computed tomography (CBCT) is a relatively new extra-oral imaging system which was
specifically developed to overcome the limitations of periapical radiographs as it produces
undistorted 3D information of the maxillofacial skeleton with a substantially lower radiation
dose compared to conventional CT.
Consequently, CBCT has the potential to become non-invasive diagnostic instrument for various
dental applications in which defect characterization, localization and volume measurements
are important.
CBCT is currently being considered as a superior diagnostic tool for applications in
periodontology. CBCT scanning was found to be more effective than other 2D imaging modalities
in assessing periodontal structures. As CBCT had better potential of detecting periodontal
bone defects in all directions compared with periapical radiographs. More over interproximal
areas also, buccal and lingual defects could not be recognized from each other with intraoral
radiographs.
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