CORRELATION OF CLINICAL AND RADIOGRAPHIC DIAGNOSIS OF CARIOUS LESIONS IN POSTERIOR TEETH

HERNÁNDEZ, JESÚS ALBERTO; CARDOZO, MARÍA ALEJANDRA; ARANGO, MARÍA CRISTINA; VILLAVICENCIO, JUDY ELENA; HERNÁNDEZ, JESÚS ALBERTO; CARDOZO, MARÍA ALEJANDRA; ARANGO, MARÍA CRISTINA; VILLAVICENCIO, JUDY ELENA

doi:10.17533/udea.rfo.v28n2a7

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Revista Facultad de Odontología Universidad de Antioquia

Print version ISSN 0121-246X

Rev Fac Odontol Univ Antioq vol.28 no.2 Medellín Jan./June 2017

https://doi.org/10.17533/udea.rfo.v28n2a7

Original article

CORRELATION OF CLINICAL AND RADIOGRAPHIC DIAGNOSIS OF CARIOUS LESIONS IN POSTERIOR TEETH^¹

JESÚS ALBERTO HERNÁNDEZ²^*

MARÍA ALEJANDRA CARDOZO³

MARÍA CRISTINA ARANGO⁴

JUDY ELENA VILLAVICENCIO⁵

^² Specialist in Pediatric Dentistry, Professor at Universidad del Valle, Cali, Colombia. Email: jesus.hernandez@correounivalle.edu.co

^³ Specialist in Pediatric Dentistry and Maxillary Orthopedics, Cali, Colombia. Email: m.alejandracb10@gmail.com

^⁴ Specialist in Pediatric Dentistry and Maxillary Or thopedics, Professor at Universidad del Valle, Cali, Colombia. Email: titiarango25@yahoo.com

^⁵ Specialist in Pediatric Dentistry, Professor at Universidad del Valle, Cali, Colombia. Email: judyvila07@gmail.com

ABSTRACT.

Introduction:

dental caries is a public health problem affecting a large percentage of the population. The carious process is highly variable and has periods of progression that alternate with periods of stability of the damaged tissue. There are different techniques to diagnose dental caries, including clinical and radiographic evaluation.

Objective:

the objective of this study was to establish correlation between the clinical and radiographic caries diagnosis suggested by ICCMSTM, in deciduous and permanent molars of a school population.

Methods:

descriptive study evaluating a sample for convenience of 1174 proximal and occlusal tooth surfaces of permanent and deciduous molars, taken from the database of 35 outpatients treated at the school of dentistry, who were clinically and radiographically evaluated for caries as recommended by the ICCMSTM based on bitewing x-rays.

Results:

the clinical and radiographic diagnosis was correlated in 1174 proximal and occlusal surfaces, with 0.41 Spearman’s rank correlation coefficient (p < 0,05). The findings suggest that 95.6% of teeth diagnosed as healthy coincided with the clinical and radiographic results; in early mild stages, there was coincidence in only 8.16% and 6.4% respectively.

Conclusions:

there is low correlation between the clinical diagnosis of caries and the radiographic examination, in relation to ICCMSTM standards.

Key words: dental caries; coronal x-ray; non-parametric statistics

RESUMEN.

Introducción:

la caries dental es un problema de salud pública que afecta a un gran porcentaje de la población. El proceso de actividad de la caries es muy variable y presenta períodos de progresión que alternan con períodos de detención del tejido dañado. Actualmente existen diversas técnicas para el diagnóstico de caries dental, entre las cuales se encuentra la evaluación clínica y radiográfica.

Objetivo:

el objetivo de este estudio consistió en establecer la correlación entre el diagnóstico clínico de caries y el diagnóstico radiográfico propuesto por el ICCMSTM, en molares temporales y permanentes de una población escolar.

Métodos:

estudio descriptivo, en el que se evaluó una muestra por conveniencia de 1174 superficies dentales proximales y oclusales de molares permanentes y temporales, tomada de la base de datos de 35 pacientes atendidos en área extramural de la escuela de odontología, los cuales fueron evaluados clínica y radiográficamente para caries según lo propuesto por el ICCMSTM a partir de radiografías aleta de mordida.

Resultados:

se correlacionó el diagnóstico clínico y radiográfico en 1174 superficies proximales y oclusales con un coeficiente de correlación de Spearman de 0,41 (p<0,05). Se encontró que el 95,6% de los dientes diagnosticados como sanos coincidió con los resultados clínicos y radiográficos; en estadios iniciales y moderados se encontró coincidencia solo en el 8,16% y 6,4% respectivamente.

Conclusiones:

hay baja correlación entre el diagnóstico clínico de caries y el examen radiográfico, según lo propuesto por ICCMSTM.

Palabras clave: caries dental; radiografía coronal; estadística no paramétrica

INTRODUCTION

Understanding dental caries, its progression and proper diagnosis in early stages has become a challenge in clinical practice, research, and prevention.¹

Tooth decay is a dynamic disease affecting the tooth’s surface in contact with biofilm, resulting in mineral loss, which leads to the localized destruction of the tooth’s hard tissue. During the early stages of the carious lesions there is an increase in enamel micro-porosity, which clinically appears as opacity or a stain that can be either white or brown. As micro-porosity increases, tooth structure collapses forming a cavity. This process is slow, and according to the evidence it can be stopped before the cavity appears.¹ However, while currently there is a decrease in caries prevalence nationwide, the percentage of this disease is still high, as reported in the 2014 National Oral Health Survey in Colombia (Estudio Nacional de Salud Bucal en Colombia -ENSAB IV), which showed that caries prevalence at age 5 was 52.38%, at age 12 it was 37.4%, and at age 15 it was 44.5%.²

The carious process is highly variable, with periods of progression alternating with periods of stability; therefore, diagnostic methods must seek to detect the aforementioned changes, in order to determine the stage at which the disease can be arrested. In consequence, the development of an effective diagnostic method has been the goal of many researchers for a long time.¹^,³^,⁴

Conventional caries diagnostic approaches include the visual-tactile method and the radiographic method, which are relatively accurate³^,⁴^,⁵ but have been modified to improve effectiveness. Therefore, within the visual-tactile method there have multiple systems of caries classification, which tend to report the initial carious lesions due to changes in their pattern of presentation.

The International Caries Classification and Management System (ICCMS^TM) uses a simplified version of the International Caries Detection and Assessment System (ICDAS). ⁶ In an attempt to improve traditional methods, unify concepts, establish treatment decisions, and better detect this type of lesions, mainly at the interproximal level, several authors recommend a combination of the visual examination with other diagnostic aids. The most commonly used complementary technique is coronal x-rays or bite-wing x-rays, which is very helpful in detecting proximal lesions.⁶^,⁷^,⁸^,⁹^,¹⁰

X-rays are useful to detect advanced tooth decay, since the demineralized tooth area allows a greater filtration of x-rays, showing as a radiolucent zone. The opposite occurs in early lesions, which do not have sufficient demineralization to be detected through x-ray. On the other hand, intraoral radiography may reveal interproximal caries, which could go unnoticed by clinicians during regular examination, but early lesions are difficult to detect by x-ray methods, especially if they are located in enamel only. Even experienced clinicians may disagree on the presence of decay by x-ray methods. Some can identify lesions on intact surfaces (false positives), while others fail to detect evident lesions (false negatives). This is why coronal x-ray as and additional diagnostic method is a useful complement to diagnose and accurately treat dental caries. In vitro studies have shown that this is the most reliable method to diagnose caries in the dentin middle third, compared with just visual inspection.⁴^,⁵

Like visual diagnostic methods, the radiographic technique has undergone changes thanks to technological advances. The conventional technique with x-ray film used to be popular in the past, while today digitized media is available, yielding better results by increasing image contrast. The 1991 studies by Wenzel et al found out increased effectiveness in digital radiographs, concluding that this technique improves diagnosis, compared with visual inspection, as it increases sensitivity without losing specificity.⁷^,¹¹

The sensitivity of radiographic images reported in several studies is low; however, it remains the complementary technique of choice for most clinicians. The 2011 study by Diniz et al reported 44% sensitivity and 94% specificity.¹²

Currently, coronal x-rays are recommended for patients over 5 years of age, in order to reduce the underreporting occurring in interproximal lesions. Radiographically, the ICCMS^TM classifies posterior tooth surfaces in various degrees according to progression, enabling good reproducibility and accuracy of this classification system.¹³^,¹⁴

The ICCMS^TM integrated the ICDAS evaluation with the proposed radiographic evaluation to detect caries lesions and their depth, in order to provide more comprehensive information to plan, manage, and properly diagnose tooth decay.¹⁵^,¹⁶^,¹⁷^,¹⁸

The goal of this study was to establish correlation between clinical and radiographic diagnosis of dental caries as proposed by the ICCMS^TM, in deciduous and permanent molars in a school population.

MATERIALS AND METHODS

A descriptive study was conducted using the clinical and radiographic database of 35 kids (20 girls and 15 boys) aged 6 to 8 years, who were treated in a public school of the city of Cali, Colombia. The sample was chosen for convenience and the analysis unit consisted of 1260 permanent and deciduous molar surfaces. The surfaces had been previously evaluated for caries and were entered in each patient’s medical record following the ICCMS^TM, which regroups the ICDAS criteria in four categories: 0 = healthy; A = initial decay in enamel, showing a white and/or brown lesion spot in either dry or wet surface (ICDAS codes 1 and 2); B = moderate decay, including the micro-cavitated lesion and the dentine lesion with an underlying shade (ICDAS codes 3 and 4), and C = severe caries, cavitated lesions with visible dentin (ICDAS codes 5 and 6). The data were entered by a dentist standardized in this index, with a 0.80 Kappa index.

Patients had bitewing x-rays taken at Universidad del Valle, all by a single assistant using the X digital GX 770 equipment (Intra Oral X-Ray System/ User Manual Dentsplay-Gendex). The x-rays were analyzed and entered in a form for caries reading and classification by the ICCMS^TM. The radiographic criteria included were: R: 0 Not Radiolucent, RA: early stage, which includes: RA1 (radiolucency in the ½ outer enamel), RA2 (radiolucency in the ½ internal enamel ± ADJ (amelodentinal junction), RA3 (radiolucency limited to the ⅓ outer dentine). RB: mild stage, which includes RB4 (radiolucency that reaches the ⅓ half of the dentin), RC: extensive stage, which includes RC5 (radiolucency reaching the ⅓ inner dentin, clinically cavitated), and RC6 (pulp radiolucency, clinically cavitated). The following data were taken into account: occlusal, mesial, and distal surfaces of first and second deciduous molars and first permanent molars, for a total of 36 surfaces per patient. The analysis was performed by two dentists previously standardized as inter- and intra- examiner, in the radiographic system proposed by ICCMS^TM, with a 0.80 Kappa index.¹³

The inclusion criteria were: mesial, occlusal, and distal surfaces of deciduous and permanent molars that were entered as part of the clinical and radiographic analysis of the medical records. The exclusion criteria were: molar surfaces that were not present in the x-ray or the odontogram, or whose crowns were not erupted in at least ⅔; 86 surfaces were excluded accordingly, leaving 1174 surfaces to analyze. Due to the greater applicability of bitewing x-rays to evaluate interproximal surfaces, a new analysis was performed with just the interproximal surfaces (806 surfaces).

Statistical analysis

The collected data were digitized in an Excel spreadsheet, which included the clinical and radiographic diagnoses per surface and tooth number. Contingency tables were made to find the frequencies of coincidence of clinical and radiographic diagnoses. Due to their ordinal nature, the clinical and radiographic diagnoses were correlated by Spearman’s correlation coefficient with 0.05 alpha, using the Epi-info statistical package, version 6.0, and Stata 11®.

The Institutional Board of Human Ethics Assessment of Universidad del Valle School of Health approved this project’s protocol by means of Agreement No 08-015. This study was funded by an internal call for projects at Universidad del Valle.

RESULTS

The clinical and radiographic diagnosis was correlated in 1174 coronal and proximal surfaces with 0.41 Spearman’s correlation coefficient (p < 0.05). Table 1 lists the results of the clinical and radiographic correlation of all surfaces, showing clinical and radiographic coincidence of a healthy diagnosis in 95.9% of cases. In early stages of tooth decay, there was 8.16% coincidence; however, 89.12% of clinically detectable lesions in early stages were recorded as healthy from a radiographic perspective.

Table 1 Clinical and radiographic correlation of dental caries in proximal and occlusal surfaces according to ICCMSTM

Clinical diagnosis proposed by ICCMSTM				Radiographic diagnosis
Clinical diagnosis proposed by ICCMSTM				Healthy	Early stage	Mild stage	Severe stage	Total
Healthy (0)	n	889	25	5	8	927
Healthy (0)	%	95.9	2.70	0.54	0.86	100
First visual change in enamel (1) Change visually detected in enamel (2)	n	131	12	2	2	147
	%	89.12	8.16	1.36	1.36	100
Microcavity detected in enamel (3) Underlying dark shade in dentin (4)	n	19	9	2	1	31
	%	61.29	29.03	6.45	3.23	100
Detectable cavity with exposed dentin (5) Extensive cavity with exposed dentin (6)	n	22	7	12	28	69
	%	33.88	10.14	17.39	40.79	100
TOTAL	n	1061	53	21	39	1174
%	90.37	4.51	1.79	3.32	100

The clinical diagnosis of mild lesions showed that coincidence with the moderate radiographic level was 6.45%. Concerning lesions clinically diagnosed as severe, 40.58% showed coincidence with the radiographic diagnosis, while 31.88% of these lesions were recorded as healthy from a radiographic perspective.

Table 2 shows the results excluding the analysis of occlusal surfaces, leaving a total of 806 interproximal surfaces with 0.48 Spearman’s correlation coefficient (p < 0.05). There was also a higher proportion of surfaces clinically and radiographically diagnosed in early stages (17.50%); similarly, the percentage of coincidence in mild stages was 16.67%, and there was 82.35% coincidence in severe stages.

Table 2 Clinical and radiographic correlation of dental caries in proximal surfaces, according to ICCMSTM

Clinical diagnostic - ICDASTM codes				Radiographic diagnosis
Clinical diagnostic - ICDASTM codes				Healthy	Early stage	Mild stage	Severe stage	Total
Healthy (0)	n	684	23	2	3	712
Healthy (0)	%	96.07	3.23	0.28	0.42	100
First visual change in enamel (1) Change visually detected in enamel (2)	n	38	7	1	0	46
	%	82.61	15.22	2.17	0.00	100
Microcavity detected in enamel (3) Underlying dark shade in dentin (4)	n	4	6	2	0	12
	%	33.33	50.00	16.67	0.00	100
Detectable cavity with exposed dentin (5) Extensive cavity with exposed dentin (6)	n	11	4	7	14	36
	%	30.56	11.11	19.44	38.89	100
Does not apply	n	737	40	12	17	806
%	91.22	4.96	1.49	2.11	100

DISCUSSION

Caries detection by radiographic means is only possible if the amount of demineralization is such that produces a change in radiation density. Bitewing x-rays have proved to be very useful to detect caries in interproximal and occlusal surfaces of deciduous and permanent molars, since direct visual inspection is not possible in all cases, as interproximal surfaces are wide and their contacts prevent correct diagnosis.¹⁹^,²⁰ This is why x-rays as a diagnostic complement is more important in clinical than in epidemiological terms.

The present study showed low correlation between the caries categories proposed by the ICCMS^TM in relation to the radiographic system proposed, in analyzing both proximal and occlusal surfaces and interproximal surfaces only; this is due perhaps to the minimal mineral loss in early lesions, which cannot be radiographically perceived. In addition, the overlying of enamel in the occlusal area can mask the mineral loss process.

The DMF index is the international standard that the WHO has been using for the control of dental caries. This index gives an average of decayed (cavitated), missed, and filled teeth, providing a report of affected teeth or surfaces. In order to achieve early detection of caries in early stages, multiple systems of caries classification have been created, and while aiming at early diagnosis, they require specific clinical conditions and the clinician’s standardization. The ICCMS^TM system proposes a series of combined caries categories, based on the ICDAS classification system, sorting them out according to depth-which is an effective alternative in both clinical practice and education, research, and epidemiology-.⁶ In addition, for a comprehensive diagnosis it proposes the ICDAS/ ICCMS^TM radiographic system, categorizing lesions according to radiographic depth.

The present study showed that when lesions were clinically classified as initial according to the ICCMS^TM, 82.61% were radiographically reported as healthy. Again, the difficulty in radiographic diagnosis of early lesions may be related to the percentage of demineralization, as it has been reported that 30 to 40% of mineral loss is necessary for the radiographic detection of enamel caries.²¹^,²²^,²³

In lesions classified as mild per the ICCMS^TM, 61.29% were radiographically classified as healthy. These results agree with the study by Bertella et al in 2012 on the x-ray pattern of mild lesions on permanent molars, evaluating the associationbetweenenamel fissure and radiographic features, finding out that 67.4% of these lesions did not show radiographic radiolucity.¹²^,²²

A second analysis was conducted excluding the occlusal surfaces, since coronal x-rays have proven to be more effective in interproximal surfaces. This analysis yielded a greater coincidence of surfaces that are clinically and radiographically diagnosed in early and mild stages. This change may be explained because the use of bitewing x-rays for occlusal caries diagnosis has been questioned, since they have been considered more useful for interproximal lesions. Nevertheless, the study by Ricketts et al found out that x-rays are better than visual examination for the diagnosis of occlusal caries only. However, the use of bitewing x-rays to diagnose these lesions should be considered as a complement to visual diagnosis instead of a highly sensitive diagnostic aid.⁵^,¹³^,¹⁴

Research results indicate that bitewing x-rays could add substantial information to the visual examination, allowing clinicians make better treatment decisions. Similarly, Rodrigues et al, in 2008, concluded that the clinical classification system combined with x-rays improved diagnosis, and suggested this combination for caries diagnosis.¹²^,²³

Other studies, such as the one by Lobo et al, have shown that bitewing x-rays can add information to the visual examination concerning the stage of the carious process in more advanced stages, including hidden cavities.¹²^,²⁴ Similar results were obtained in the present study, where extensive cavities coincided in a higher percentage with the radiographic diagnosis, indicating that bitewing x-ray examination provides more accurate information in advanced stages. In 1991, Tveit et al found out that x-rays were more successful in the diagnosis of dentine caries, where 100% of deep lesions were correctly diagnosed.²⁵

In the same way, Mitropoulos et al, in 2010, noted that visual inspection was more accurate than x-rays in the detection of initial enamel lesions, while the opposite happened in extensive lesions, which may indicate that x-rays are more useful to diagnose deep lesions.¹⁸

The present study makes useful contributions to the knowledge on the use of radiographs as a diagnosis method accompanied by the clinical diagnosis proposed by the ICCMS^TM, recognizing the importance of x-rays to define the depth of dentin lesions, rather than using them for early diagnosis.

Within the limitations of this study is the fact that the results are applicable exclusively to the evaluated population, and that the sample size, while being for convenience, fails to represent the entire population of this age; in addition, it has the limitations of this type of design. Further research is required to evaluate diagnosis and to make comparison with different methods, as well as studies on clinical and radiographic classification, helping the decision making process. Additional studies on clinical and radiographic correlation are also recommended, using different clinical and radiographic classification systems, using coronal x-ray in order to determine the most useful and accurate method in the clinical practice.

CONCLUSIONS

Based on the results of this study, the following conclusions can be drawn:

- There is low clinical and radiographic correlation in the early stages of tooth decay, according to the criteria used by the ICCMS^TM.
- The clinical and radiographic correlation increases in mild and severe stages.
- Bitewing x-ray is a complement in the correct diagnosis of interproximal caries, and is useful to confirm the presence of caries in this area when needed.
- Additional studies are needed to evaluate correct diagnosis and to compare different methods.

REFERENCES

1. Ismail AI. Clinical diagnosis of precavitated carious lesions. Community Dent Oral Epidemiol 1997; 25(1): 13-23. [ Links ]

2. Colombia. Ministerio de Salud y Protección Social. IV Estudio nacional de salud bucal. ENSAB IV: para saber cómo estamos y saber qué hacemos. Bogotá: Ministerio de Salud y Protección Social; 2014. [ Links ]

3. Fejerskov O, Kidd E. Dental caries: the disease and its clinical management. 2 ed. Singapore: Blackwell Munksgaard; 2008. [ Links ]

4. Ricketts DN, Kidd EA, Smith BG, Wilson RF. Clinical and radiographic diagnosis of occlusal caries: a study in vitro. J Oral Rehabil 1995; 22(1): 15-20. [ Links ]

5. Pereira AC, Eggertsson H, Martinez-Mier EA, Mialhe FL, Eckert GJ, Zero DT. Validity of caries detection on occlusal surfaces and treatment decisions based on results from multiple caries-detection methods. Eur J Oral Sci 2009; 117(1): 51-57. DOI:10.1111/j.1600-0722.2008.00586.x URL:https://doi.org/10.1111/j.1600-0722.2008.00586.x [ Links ]

6. Pitt NB, Ismail AI, Martignon S, Ekstrand K, Douglas VA, Longbottom C. ICCMS ™ guide for practitioners and educators. London: King’s College London; 2014. [ Links ]

7. Angmar-Månsson B, ten-Bosch JJ. Advances in methods for diagnosing coronal caries: a review. Adv Dent Res 1993; 7(2): 70-79. DOI:10.1177/08959374930070021801 URL:https://doi.org/10.1177/08959374930070021801 [ Links ]

8. Friedman J, Marcus MI. Transillumination of the oral cavity with the use of fiber optics. J Am Dent Assoc 1970; 80(4): 801-809. [ Links ]

9. Hernández JR, Gómez JF. Determinación de la especificidad y sensibilidad del ICDAS y fluorescencia Láser en la detección de caries in vitro. Rev ADM 2012; 69(3): 120-124. [ Links ]

10. Rock WP, Kidd EA. The electronic detection of demineralisation in occlusal fissures. Br Dent J 1988; 164(8): 243-247. [ Links ]

11. Wenzel A, Hintze H, Mikkelsen L, Mouyen F. Radiographic detection of occlusal caries in non-cavitated teeth. A comparison of conventional film radiographs, digitized film radiographs, and RadioVisioGraphy. Oral Surg Oral Med Oral Pathol 1991; 72(5): 621-626. [ Links ]

12. Diniz MB, Lima LM, Eckert G, Zandona AG, Cordeiro RC, Pinto LS. In vitro evaluation of ICDAS and radiographic examination of occlusal surfaces and their association with treatment decisions. Oper Dent 2011; 36(2): 133-142. DOI:10.2341/10-006-L URL:https://doi.org/10.2341/10-006-L [ Links ]

13. Ekstrand KR, Ricketts DN, Kidd EA: Reproducibility and accuracy of three methods for assessment of demineralization depth of the occlusal surface: an in vitro examination. Caries Res 1997; 31(3): 224-231. [ Links ]

14. Ricketts DN, Ekstrand KR, Kidd EA, Larsen T. Relating visual and radiographic ranked scoring systems for occlusal caries detection to histological and microbiological evidence. Oper Dent 2002; 27(3): 231- 237. [ Links ]

15. Pitts NB, Ekstrand KR. ICDAS Foundation. International Caries Detection and Assessment System (ICDAS) and its International Caries Classification and Management System (ICCMS TM): methods for staging of the caries process and enabling dentists to manage caries. Community Dent Oral Epidemiol 2013; 41(1): e41-e52. DOI:10.1111/cdoe.12025 URL:https://doi.org/10.1111/cdoe.12025 [ Links ]

16. Pitts NB, Stamm J. International Consensus Workshop on Caries Clinical Trials (ICW-CCT): final consensus statements: agreeing where the evidence leads. J Dent Res 2004; 83: C125-C128 [ Links ]

17. Ismail AI, Sohn W, Tellez M. The International Caries Detection and Assessment System (ICDAS): an integrated system for measuring dental caries. Community Dent Oral Epidemiol 2007; 35(3): 170-178. DOI:10.1111/j.1600-0528.2007.00347.x URL:https://doi.org/10.1111/j.1600-0528.2007.00347.x [ Links ]

18. Mitropoulos P, Rahiotis C, Stamatakis H, Kakaboura A. Diagnostic performance of the visual caries classification system ICDAS II versus radiography and micro-computed tomography for proximal caries detection: an in vitro study. J Dent 2010: 38(11): 859-867. DOI:10.1016/j.jdent.2010.07.005 URL:https://doi.org/10.1016/j.jdent.2010.07.005 [ Links ]

19. White S, Pharoah MJ. Radiología oral: principios e interpretación. 4 ed. Madrid: Harcourt; 2002. [ Links ]

20. Arango MC, Zapata AM, Saldarriaga A. Caries dental en escolares incluyendo evaluación radiográfica de lesiones proximales. [Tesis de grado Especialista en Odontopediatría]. Medellín: Universidad CES. Facultad de Odontología; 2014 [ Links ]

21. Ari T, Ari N. The performance of ICDAS-II using lowpowered magnification with light-emitting diode headlight and alternating current impedance spectroscopy device for detection of occlusal caries on primary molars. ISRN Dent 2013; 2013: 276070. DOI:10.1155/2013/276070 URL:https://doi.org/10.1155/2013/276070 [ Links ]

22. Bertella N, Moura dos S, Alves LS, Damé-Teixeira N, Fontanella V, Maltz M. Clinical and radiographic diagnosis of underlying dark shadow from dentin (ICDAS 4) in permanent molars. Caries Res, 2013: 47(5): 429-432. DOI:10.1159/000350924 URL: https://doi.org/10.1159/000350924 [ Links ]

23. Rodrigues JA, Hug I, Diniz MB, Lussi A. Performance of fluorescence methods, radiographic examination and ICDAS II on occlusal surfaces in vitro. Caries Res 2008; 42(4): 297-304. DOI:10.1159/000148162 URL:https://doi.org/10.1159/000148162 [ Links ]

24. Lobo MM, Pecharki GD, Gushi LL, Silva DD, Cypriano S, Meneghim MC et al. Occlusal caries diagnosis and treatment. Braz J Oral Sci 2003; 2(6): 239-244. [ Links ]

25. Tveit AB, Espelid I, Fjelltveit A. Radiographic diagnosis of occlusal caries. J. Dent. Res 1991; 70(Suppl 1): 494. [ Links ]

¹ Institutional affiliation: Universidad del Valle. Internal call for submissions 1-2014, for the formation of a research projects bank.

Hernández JA, Cardozo MA, Arango MC, Villavicencio JE. Correlación del diagnóstico clínico y radiográfico de la lesión de caries en dientes posteriores. Rev Fac Odontol Univ Antioq 2017; 28(2): 341-353. DOI:10.17533/udea.rfo.v28n2a7 URL:http://dx.doi.org/10.17533/udea.rfo.v28n2a7

CONFLICT OF INTEREST The authors declare not having any conflict of interest.

Received: February 08, 2016; Accepted: March 21, 2017

^*CORRESPONDING AUTHOR Jesús Alberto Hernández Silva Universidad del Valle (+57) 314 887 1384 jesus.hernandez@correounivalle.edu.co Calle 5 # 38-10, oficina 707 Cali, Colombia

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