Original research

Stomatology

Carlos Cesar DE ANTONI(a) 
Mariza Akemi MATSUMOTO(b) 
Andréia Aparecida da SILVA(a) 
Marcos Martins CURI(c) 
Joel Ferreira SANTIAGO JÚNIOR(a) 
Laurindo Moacir SASSI(d) 
Camila Lopes CARDOSO(a)

 (a) Universidade do Sagrado Coração, 
Department of Oral Surgery, Bauru, SP, Brazil.

 (b) Universidade Estadual Paulista, Department 
of Histology, Araçatuba, SP, Brazil.

 (c) Hospital Santa Catarina, Department of 
Stomatology, São Paulo, SP, Brazil.

 (d) Hospital Erasto Gaertner, Department of 
Oral Surgery, Curitiba, PR, Brazil.

Medication-related osteonecrosis 
of the jaw, osteoradionecrosis, 
and osteomyelitis: A comparative 
histopathological study

Abstract: It is largely known that some oral diseases can be diagnosed 
based upon their clinical manifestation combined with the patient’s 
medical history and generally not depending on histopathological 
examination. This is the case of some bone diseases such as 
osteoradionecrosis of the jaw (ORNJ), osteomyelitis of the jaw (OMJ), 
and medication-related osteonecrosis of the jaw (MRONJ). The 
present study aimed to analyze the histopathological features of these 
specific bone diseases in order to evaluate similarities and differences. 
Forty-four bone specimens resected from each bone disease (22 cases of 
ORNJ, 6 cases of OMJ, and 16 cases of MRONJ) were analyzed by two 
experienced oral pathologists without prior knowledge of the diagnosis, 
considering bone tissue condition, inflammation, vascularization, and 
the presence of microorganisms. In addition, the examiners formulated 
a diagnostic hypothesis for each specimen. Many histopathological 
similarities were found among the diseases, especially considering 
the presence of necrotic bone, inflammation, and microorganisms. 
Statistically significant differences were detected in empty bone 
lacunae, which was decreased in ORN (p = 0.042), and considering 
neutrophil count, which was low in the MRONJ group (p ≤ 0.001). The 
Kappa coefficient was calculated and agreement was detected based 
on the histopathological parameters, but not for diagnostic suggestion 
(p=0.23). In conclusion, histopathological aspects of ORNJ, OMJ, 
and MRONJ do not permit a conclusive diagnosis, emphasizing the 
necessity of a detailed clinical report. 

Keywords: Osteonecrosis; Osteomyelitis; Osteoradionecrosis.

Introduction

Histopathological analysis may be critical for confirming the diagnosis 
of many craniomaxillofacial diseases. However, ideally, the combination 
of clinical findings and complementary exams should be followed, since 
specific conditions such as those affecting bone tissue may present quite 
similar histological features. Among them, particular attention is given to 
osteomyelitis (OMJ), osteoradionecrosis (ORNJ), and medication-related 
osteonecrosis of the jaw (MRONJ).1,2,3 However, it is important to emphasize 

Declaration of Interests: The authors 
certify that they have no commercial or 
associative interest that represents a conflict 
of interest in connection with the manuscript.

Corresponding Author:
Camila Lopes Cardoso 
E-mail: cardoso_lopes@yahoo.com.br

https://doi.org/10.1590/1807-3107bor-2018.vol32.0023

Submitted: September 19, 2017 
Accepted for publication: January 31, 2018 
Last revision: February 16, 2018

1Braz. Oral Res. 2018;32:e23



Medication-related osteonecrosis of the jaw, osteoradionecrosis, and osteomyelitis: A comparative histopathological study 

that these are quite distinct clinical pathologies with 
different etiologies.2 

Osteomyelitis (OMJ) is a bone pathology which 
generally occurs due to complications arising 
from an acute dentoalveolar abscess and is caused 
by the microbial infection with eventual tissue 
destruction and necrosis, extending beyond the 
initial area of involvement.4  Regarding bone necrosis, 
osteoradionecrosis of the jaw (ORNJ) is a common and 
serious complication following head and neck radiation 
therapy,5  and medication-related osteonecrosis 
(MRONJ) is considered the most common complication 
associated with bisphosphonate therapy.6

Bone necrosis is a common characteristic of 
these bone diseases, which also have clinical signs 
and symptoms.2 Despite histopathological and 
clinical similarities, the above-mentioned pathologies 
also exhibit very similar image characteristics.7,8 
Authors have presented a detailed image description 
comparing BRONJ and ORNJ from dental panoramic 
radiographs and computed tomography and have 
pointed out a number of similarities between the 
two pathologies, such as osteolysis, osteosclerosis, 
sequestration, and dissemination of soft tissue 
inflammation, emphasizing only two main differences 
between them, namely predominant osteolysis in 
ORNJ and osteosclerosis in MRONJ cases.7  

There are few pathological studies comparing OMJ, 
MRONJ, and ORNJ in the literature.1,2,3,9 Therefore, the 
present study aimed to compare the histopathological 
features of these bone diseases in order to detect 
some common or prevalent aspects. 

Methodology

A retrospective histopathological evaluation was 
performed on specimens selected from patients’ 
records from 2000 to 2017, previously subjected to 
biopsy of the maxillary bones and diagnosed as OMJ, 
ORNJ, and MRONJ associated with bisphosphonate. 
The final diagnosis of each disease was recorded 
in the patients’ medical records and it was based 
on clinical, radiographic, and microscopic aspects, 
combined with the medical history. This study 
was approved by the institutional review board 
(process no. 1.249.820). The patients’ records were 

reviewed and the following clinical criteria were 
used for the diagnosis of OMJ: presence of bone 
infection, suppuration and radiographic evidence 
of osteolysis, absence of head and neck radiation 
therapy, and no use of bisphosphonates.2,4 The 
diagnostic criteria for MRONJ were the presence 
of exposed necrotic bone in the jaws for at least 
8 weeks associated with bisphosphonate use and 
absence of head and neck radiation therapy.2,6 The 
diagnostic criteria for ORNJ were the presence 
of exposed necrotic bone in the jaws for at least 
8 weeks in a patient who received at least 50 Gy 
of head and neck radiation therapy and absence 
of bisphosphonate therapy.5

The specimens were obtained from existing 
paraffin-embedded blocks of each bone disease from 
three different institutions. Microscope slides were 
cut in 6-μm sections and stained with hematoxylin 
and eosin (HE), and analyzed by two experienced 
oral pathologists, who were blinded to the diagnosis. 
The following parameters were considered for the 
histopathological analysis: overall bone tissue status 
(vitality, necrosis, reactivity), bone cells (osteoblasts, 
osteoclasts), inflammation, vascularization (blood 
vessels, thrombosis), and presence of biofilm. The 
detailed criteria are displayed in Table 1, where 
the examiners marked the absence or presence of 
each item, and at the end, each pathologist made a 
presumptive diagnosis, limited to the three diseases. 
After the evaluation, the diagnoses were compared 
with the original ones.

Table 1. Microscopic evaluation criteria.

Bone evaluation

Necrotic bone

Reactive bone

Osteoclast

Osteoblast

Empty osteocyte lacunae

Inflammation

Lymphocytes

Macrophages

Neutrophils

Vascularization
Blood vessels

Hyperemia and thrombosis

Microorganisms Present or absent

2 Braz. Oral Res. 2018;32:e23



De Antoni CC, Matsumoto MA, Silva AA, Curi MM, Santiago Júnior JF, Sassi LM et al.

The data were fed into an Excel spreadsheet 
(Microsoft Office Excel, Redmond, WA, USA), analyzed 
by SigmaPlot software (SigmaPlot, San Jose, CA, 

USA) version 12.3, and their normal distribution and 
equal variance were checked by the Shapiro-Wilk 
test, followed by the Kruskal-Wallis test (one-way 

Figure 1. a, b) MRONJ – extensive biofilms on the surfaces of non-viable bone tissue; c) OMJ – Non-viable bone tissue presenting 
basophilic reversal lines, d) biofilm with leukocyte infiltration; and, e, f) ORNJ – Avascular and acellular bone tissue showing areas 
with osteoclastic activity (HE; bar = 100 µm).

A B

C D

E F

3Braz. Oral Res. 2018;32:e23



Medication-related osteonecrosis of the jaw, osteoradionecrosis, and osteomyelitis: A comparative histopathological study 

analysis of variance on ranks (variable: Diagnosis)) 
and Dunn’s post-hoc test, in order to verify the 
differences between groups at a 5% significance level. 
The agreement between the different factors evaluated 
by examiners (1 and 2) was interpreted by a Kappa 
interrater coefficient. The actual diagnoses made 
by examiners were compared by a Kappa statistic, 
and the results were shown according to the actual 
clinical condition or final diagnosis.

Results

Forty-four bone specimens resected from each 
bone disease comprising 22 cases of ORNJ, 6 cases of 
OMJ, and 16 cases of MRONJ were included. Thickness 
and percentage of bone tissue and connective tissue 
varied considerably, as the specimens were obtained 
from incisional biopsies. Minimum thickness was 
5 mm. All specimens had the ideal thickness required 
for diagnosis.

The demographic data are displayed in Table 2 
The concordance between the different factors 
evaluated by examiners (1 and 2) was interpreted 
by a Kappa interrater coefficient, which was equal 
to 1, that is, there was no interrater difference 
in the evaluation of the presence or absence of 
each variable. Most of the analyzed criteria were 
detected in MRONJ, ORNJ, and OMJ, as shown 
in Table 1, resulting in no statistically significant 
differences in their prevalence rates. The percentages 

of all evaluated structures are described in Table 
3, including general aspects of bone tissue, such as 
necrotic (p = 0.211) and reactive bone (p = 0.723), 
along with osteoclastic (p = 0.146) and osteoblastic 
cells (p = 0.432). In addition, the rate inflammation 
(p = 0.672), especially chronic, was the same for 
all the three diseases, considering lymphocytes 
(p = 0.054) and macrophages (p = 0.490). Also, the 
presence of blood vessels (p = 0.870) and hyperemia 
and thrombosis (p = 0.472) was similar. Another 
common finding was the presence of biofilm-forming 
microorganisms (p = 0.160) (Table 3).

Significant differences were detected in empty 
osteocyte lacunae, which were less frequent in ORNJ 
(p = 0.042) than in MRONJ and OMJ, and neutrophils, 
which were less frequent in MRONJ (p < 0.05) than 
in ORNJ and OMJ (Table 3). 

There was no consistent histopathological 
diagnosis between examiners (Kappa = 0.23). The 
tentative diagnosis made by each examiner is 
described in Table 4.

Discussion

This study aimed to evaluate the histopathological 
aspects of OMJ, ORNJ, and MRONJ considering close 

Table 2. Table showing incidence rates by gender, age, and 
lesion sites.

Bone pathologies Gender Age (years) Site 

6 OMJ samples 

5 Males - -

1 Females
53 to 56 

(mean: 54.3)
6 Mandible

22 MRONJ 
samples

4 Males - -

18 Females
43 to 89 

(mean: 58.5)
19 Mandible

- - 3 Maxilla

16 ORN samples 

15 Males - -

1 Females
42 to 75 

(mean: 58.1)
16 Mandible

Table 3. Table showing the percentage of all variables 
compared among the diseases.

Variable OMJ MRONJ ORNJ p-value

Necrotic bone 83.3 93.7 100 0.211

Osteoclast 33.3 18.7 50 0.146

Reactive bone 50 31.2 36.6 0.723

Osteoblastic coating 50 31.2 22.7 0.432

Empty osteocyte lacunae 83.3 100 22.7 0.042

Inflammation 83.3 75 86.6 0.672

Lymphocytes 66.6 43.7 81.8 0.054

Macrophages 50 31.2 50 0,490

Neutrophils 83.3 12.5 86.3 ≤ 0.001

Blood vessels 66.6 56.2 54.5 0.870

Hyperemia and thrombosis 50 43.7 63.3 0.472

Microorganisms 50 87.5 100 0.160

4 Braz. Oral Res. 2018;32:e23



De Antoni CC, Matsumoto MA, Silva AA, Curi MM, Santiago Júnior JF, Sassi LM et al.

similarities among them and, consequently, to make 
clinicians aware of the importance of understanding 
the etiopathogenesis and clinical manifestations of 
each disease. Few studies with the same objectives 
were found in a recent review of the literature;1,3,10,11 
but more information was needed in order to clarify 
histological differences between the diseases. 

It is important to emphasize that the pathologies 
chosen in the present study had already been diagnosed 
based upon the patients’ clinical information given by 
the clinicians. Since the information was retrieved from 
the files of an oral pathology service, the number of 
cases was not identical, but all cases were maintained 
in the study, thus avoiding the significant reduction 
of sample size to a minimum. Another important 
aspect refers to OMJ. It is true that MRONJ and ORNJ 
can easily evolve into osteomyelitis once secondary 
infection occurs,12 which can hinder the final diagnosis 
as well as the comprehension of the etiological process 
of each disease. However, according to the patients’ 
records, only those cases originating from chronic or 
acute dentoalveolar abscesses were chosen, with no 
association with radiation therapy or bisphosphonates, 
or with any other antiresorptive drug. 

The analysis of the histological criteria was based 
on their presence or not, and no morphometric 
method was used to quantify cells or structures, as 
this is not a routine practice for the analyzed diseases. 
Nevertheless, most of the analyzed criteria did not 
reveal significant differences, but it was clear that 
some of them were more prevalent in one or other 
disease. These aspects will also be discussed in order 
to elucidate some subtleties of each disease. Also, 
regarding the methodology, the morphometric analysis 
was not performed mainly due to the large variability 
in sample size, since the study was performed with 
biopsy specimens from different patients performed 
by different surgeons.

The presence of necrotic bone was fairly common 
among the clinical diseases. Marx and Tursun2 
identified necrotic bone in 100 of all OMJ, ORNJ, and 
MRONJ specimens, considering a set of characteristics 
such as the presence of empty osteocyte lacunae, 
absence of osteoblastic rimming, and empty Haversian 
and Volkmann canals. Although these characteristics 
were individually analyzed in our study, they were 

Table 4. Tentative diagnosis of each examiner per sample, 
indicating lack of consistency between them (Kappa=0.23).

Examiner 1 Examiner 2 Final Diagnosis

OM OMMBF ORN

OM OM ORN

OMMBF OM ORN

OM OM ORN

OMMBF OMMBF ORN

OMMBF OM ORN

OMMBF ORN ORN

OMMBF ORN ORN

OM OMMBF ORN

OMMBF OMMBF ORN

OMMBF OMMBF ORN

OM OM ORN

OM ORN ORN

OM OM ORN

OM OM ORN

OM OM ORN

ORN ORN ORN

OM OM ORN

OM OM ORN

OM ORN ORN

OM OMMBF ORN

OM ORN ORN

OM OM OM

OM ORN OM

ORN ORN OM

OMMBF ORN OM

OMMBF OMMBF OM

OM ORN OM

OMMBF ORN OMMBF

OM OMMBF OMMBF

ORN OMMBF OMMBF

OM OMMBF OMMBF

OM ORN OMMBF

OM OM OMMBF

OM OMMBF OMMBF

OM ORN OMMBF

OMMBF OMMBF OMMBF

OM OM OMMBF

ORN ORN OMMBF

OM ORN OMMBF

OM OM OMMBF

OMMBF OMMBF OMMBF

OM OMMBF OMMBF

OM ORN OMMBF

5Braz. Oral Res. 2018;32:e23



Medication-related osteonecrosis of the jaw, osteoradionecrosis, and osteomyelitis: A comparative histopathological study 

also taken as characteristics that compounded the 
general picture of bone necrosis. 

Although there was no significant difference in 
the presence of osteoclasts among the three clinical 
diseases, it was clear that they were lower in MRONJ 
specimens than in the other diseases, possibly due to 
the mechanism of action of the drug involved in the 
osteonecrotic process. Interestingly, in the study of 
Marx and Tursun,2 osteoclasts were seen only in OMJ 
specimens. The same occurred in reactive bone and 
osteoblastic coating. Despite the lack of significant 
difference among the diseases, OMJ specimens 
showed larger amounts of both criteria. 

When inflammation was assessed, more than 75 
of the samples revealed presence of some kind of 
leukocytes, and neutrophils were more frequent in 
OMJ (83.3) and ORNJ specimens (86.3). Significant lack 
of leukocytes was detected in MRONJ, in agreement 
with Marx and Tursun.2 

Compromised vascularization was expected to 
be seen, especially in ORNJ and MRONJ, given the 
etiological factors of both diseases. When the diseases 
were compared, no significant differences were detected. 
Hyperemia and thrombosis predominated in ORNJ 
(63.3), followed by OMJ (50) and MRONJ (43.7). There 
was absence of blood vessels in MRONJ samples.10 

Microorganisms were found in many samples, 
revealing no significant differences among the 
diseases. In OMJ, microorganisms were observed 
in 50 of the samples, compared to 87.5 and 100 in 
ORNJ and MRONJ, respectively. Microorganisms 

of the genus Actinomyces have been found in these 
diseases by several authors,6,13,14,15,16 including by Marx 
and Tursun2 The microorganisms were detected on 
trabecular bone surfaces in 76 of MRONJ and in 58 of 
ORNJ cases. In OMJ samples, these microorganisms 
were found in medullary spaces.2 On the other hand, 
in our study, OMJ samples showed a lower amount 
of microorganisms, compared to the other samples. 
It is important to emphasize that only 6 OMJ samples 
were evaluated in the present study.

Another aim of this study was to test oral 
pathologists’ capacity to establish a histopathological 
diagnosis of the proposed diseases in the absence 
of clinical information. Pathologists who work with 
diagnoses and know the three entities know that 
anamnesis is crucial for the diagnosis, given that 
clinical and radiographic features are very similar. 

With regard to the first research question, the 
blinded evaluation by two oral pathologists confirmed 
the hypothesis that it is not possible to establish a final 
diagnosis only by way of microscopic analysis. The 
diagnoses of the diseases mentioned above tended 
to be quite similar microscopically, as unanimously 
endorsed by experts.

Conclusions

The histopathological aspects of ORNJ, OMJ, 
and MRONJ do not permit a conclusive diagnosis, 
emphasizing the necessity of a detailed clinical report 
and of clinicians’ expertise. 

1. Guimarães EP, Pedreira FR, Jham BC, Carli ML, Pereira 

AA, Hanemann JA. Clinical management of suppurative 

osteomyelitis, bisphosphonate-related osteonecrosis, 

and osteoradionecrosis: report of three cases and review 

of the literature. Case Rep Dent. 2013;2013:402096. 

https://doi.org/10.1155/2013/402096

2. Marx RE, Tursun R. Suppurative osteomyelitis, bisphosphonate 

induced osteonecrosis, osteoradionecrosis: a blinded 

histopathologic comparison and its implications for the 

mechanism of each disease. Int J Oral Maxillofac Surg. 2012 

Mar;41(3):283–9. https://doi.org/10.1016/j.ijom.2011.12.016

3. Mitsimponas KT, Moebius P, Amann K, Stockmann P, Schlegel 

KA, Neukam FW et al. Osteo-radio-necrosis (ORN) and 

bisphosphonate-related osteonecrosis of the jaws (BRONJ): 

the histopathological differences under the clinical similarities. 

Int J Clin Exp Pathol. 2014 Jan;7(2):496–508.  

4. Lew DP, Waldvogel FA. Osteomyelitis. 

Lancet 2004;364(9431):369-79. 

https://doi.org/10.1016/S0140-6736(04)16727-5

5. Marx RE. Osteoradionecrosis: a new concept of its 

pathophysiology. J Oral Maxillofac Surg. 1983 May;41(5):283–

8. https://doi.org/10.1016/0278-2391(83)90294-X  

References

6 Braz. Oral Res. 2018;32:e23



De Antoni CC, Matsumoto MA, Silva AA, Curi MM, Santiago Júnior JF, Sassi LM et al.

6. Ruggiero SL, Dodson TB, Fantasia J, Goodday R, 

Aghaloo T, Mehrotra B et al. American Association of 

Oral and Maxillofacial Surgeons position paper on 

medication-related osteonecrosis of the jaw: 2014 update. 

J Oral Maxillofac Surg. 2014 Oct;72(10):1938–56. 

https://doi.org/10.1016/j.joms.2014.04.031

7. Obinata K, Shirai S, Ito H, Nakamura M, Carrozzo M, 

Macleod I et al. Image findings of bisphosphonate related 

osteonecrosis of jaws comparing with osteoradionecrosis. 

Dentomaxillofac Radiol. 2017 Jul;46(5):20160281. 

https://doi.org/10.1259/dmfr.20160281  

8. Cardoso CL, Barros CA, Curra C, Fernandes LM, Franzolin 

SO, Ferreira Júnior JS et al. Radiographic findings in patients 

with medication-related osteonecrosis of the jaw. Int J Dent. 

2017;2017:3190301. https://doi.org/10.1155/2017/3190301  

9. Curi MM, Cardoso CL, Lima HG, Kowalski LP, Martins 

MD. Histopathologic and histomorphometric analysis of 

irradiation injury in bone and the surrounding soft tissues 

of the jaws. J Oral Maxillofac Surg. 2016 Jan;74(1):190–9. 

https://doi.org/10.1016/j.joms.2015.07.009

10. Hansen T, Kunkel M, Weber A, James Kirkpatrick 

C. Osteonecrosis of the jaws in patients treated 

with bisphosphonates - histomorphologic analysis 

in comparison with infected osteoradionecrosis. 

J Oral Pathol Med. 2006 Mar;35(3):155–60. 

https://doi.org/10.1111/j.1600-0714.2006.00391.x

11. Carmagnola D, Canciani E, Sozzi D, Biglioli F, Moneghini L, 

Dellavia C. Histological findings on jaw osteonecrosis associated 

with bisphosphonates (BONJ) or with radiotherapy (ORN) in 

humans. Acta Odontol Scand. 2013 Nov;71(6):1410–7. 

https://doi.org/10.3109/00016357.2013.765592  

12. Tardast A, Sjöman R, Løes S, Abtahi J. Bisphosphonate associated 

osteomyelitis of the jaw in patients with bony exposure: prevention, a 

new way of thinking. J Appl Oral Sci. 2015 May-Jun;23(3):310–4. 

https://doi.org/10.1590/1678-775720140506 PMID:26221926

13. Aftimos V, Zeinoun T, Bou Tayeh R, Aftimos G. Bisphosphonate 

related osteonecrosis of the jaw: a study of 18 cases associated 

with fungal infection. Int J Dent. 2014;2014:869067. 

https://doi.org/10.1155/2014/869067 PMID:24696686

14. Boff RC, Salum FG, Figueiredo MA, Cherubini K. Important aspects 

regarding the role of microorganisms in bisphosphonate-related 

osteonecrosis of the jaws. Arch Oral Biol. 2014 Aug;59(8):790–9. 

https://doi.org/10.1016/j.archoralbio.2014.05.002  

15. Curi MM, Dib LL, Kowalski LP, Landman G, Mangini C. 

Opportunistic actinomycosis in osteoradionecrosis of the jaws 

in patients affected by head and neck cancer: incidence and 

clinical significance. Oral Oncol. 2000 May;36(3):294–9. 

https://doi.org/10.1016/S1368-8375(99)00080-9

16. De Ceulaer J, Tacconelli E, Vandecasteele SJ. Actinomyces 

osteomyelitis in bisphosphonate-related osteonecrosis of the jaw 

(BRONJ): the missing link? Eur J Clin Microbiol Infect Dis. 2014 

Nov;33(11):1873–80. https://doi.org/10.1007/s10096-014-2160-5  

7Braz. Oral Res. 2018;32:e23