Intraarticular Osteoid Osteoma: MRI Characteristics and Clinical Presentation Before and After Radiofrequency Ablation Compared to Extraarticular Osteoid Osteoma

Thomas Germann; Marc-André Weber; Burkhard Lehner; Laurent Kintzele; Iris Burkholder; Hans-Ulrich Kauczor; Christoph Rehnitz

doi:10.1055/a-1181-9041

RöFo - Fortschritte auf dem Gebiet der Röntgenstrahlen und der bildgebenden Verfahren, Table of Contents

Rofo 2020; 192(12): 1190-1199
DOI: 10.1055/a-1181-9041

Musculoskeletal System

Intraarticular Osteoid Osteoma: MRI Characteristics and Clinical Presentation Before and After Radiofrequency Ablation Compared to Extraarticular Osteoid Osteoma

Article in several languages: English | deutsch

Thomas Germann

¹Diagnostic and Interventional Radiology, University Hospital Heidelberg, Germany

,

Marc-André Weber

²Diagnostic and Interventional Radiology, University Hospital Rostock, Germany

,

Burkhard Lehner

³Department of Orthopaedics Emergency Surgery and Paraplegia, University Hospital Heidelberg, Germany

,

Laurent Kintzele

¹Diagnostic and Interventional Radiology, University Hospital Heidelberg, Germany

,

Iris Burkholder

⁴StaBiL, Statistical and Biometric Solutions, Zweibrücken, Germany

,

Hans-Ulrich Kauczor

¹Diagnostic and Interventional Radiology, University Hospital Heidelberg, Germany

,

Christoph Rehnitz

¹Diagnostic and Interventional Radiology, University Hospital Heidelberg, Germany

› Author Affiliations

Abstract

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Key words

osteoid osteoma - intraarticular - radiofrequency (RF) ablation - MRI

Introduction

Osteoid osteoma (OO) is a common bone tumor and accounts for approximately 10 % of all benign bone lesions as well as 3 % of all primary bone tumors [1]. It usually occurs in the second or third decade of life. Men are affected slightly more frequently than women (3:1) [2]. It is primarily located in the metaphyses and diaphyses of the long bones. However, approximately 13 % of OOs are intraarticular [2]. While there are numerous studies on extraarticular OOs with large case numbers, intraarticular OOs have primarily only been included in case reports, with the most common manifestations being in the hip joint [3] [4], the elbow joint [5] and the ankle joint [6]. The clinical and morphological appearance of an intraarticular OO is often atypical and differs from that of an extraarticular OO [7]. The published case reports usually showed an incorrect initial primary diagnosis. Nonspecific symptoms like limited mobility, flexion deformities, muscle atrophy, and arthritic changes are not uncommon [8]. The typical sclerosis is less pronounced on CT [9] [10] and scintigraphy may not show the classic features [11] so that the nidus cannot always be definitively identified. This presents a diagnostic challenge and can greatly delay correct diagnosis as well as any necessary treatment. However, early intervention is extremely important particularly in the case of intraarticular OO to avoid potential subsequent damage like skeletal deformities and irreversible defects of the articular cartilage due to chronic synovitis [12]. Computed tomography (CT)-guided radiofrequency ablation (RFA) is an efficient treatment option [13]. Magnetic resonance imaging (MRI) has become a valuable tool for the diagnosis of OO since it can easily visualize the nidus and reactions in the surrounding areas such as bone marrow edema and soft tissue edema as well as joint effusion and synovitis [14]. This study examines the MRI features and clinical characteristics of intraarticular compared to extraarticular OO and their occurrence before and after RFA.

Materials and Methods

Ethical principles, inclusion, and exclusion criteria

This study was approved by the ethics committee. After a thorough patient briefing regarding the type of procedure and possible risks, all patients provided written informed consent prior to the examination. The present study was performed in its current form in accordance with the Declaration of Helsinki. All patients with intraarticular OO who underwent CT-guided RFA in our institution between January 2009 and December 2018 and who had undergone a prior MRI examination were included in the study. The same number of consecutive patients with extraarticular OO in a comparable anatomical location with an available preinterventional MRI examination were included as a comparison group. In addition, a preinterventional CT image dataset was available for all patients. The diagnosis of OO was made based on the clinical presentation and morphological criteria. The most important diagnostic criterion was the detection of a nidus which was successful in all cases on MRI and was able to be confirmed on CT. In agreement with other work groups, histological confirmation was not used for diagnosis [15] [16]. Patients with other underlying tumors and patients who did not undergo RFA or for whom no preinterventional MRI examination was available were not taken into consideration.

Patient group

In this retrospective case control study, CT-guided RFA to treat an OO was performed during the study period at our institution in n = 150 patients. Intraarticular OO was seen in n = 24 patients. An OO was defined as intraarticular if the nidus was within the articular capsule. n = 3 patients were excluded since an MRI examination performed prior to RFA was not available. In total there were n = 21 patients with intraarticular OO that fulfilled all inclusion criteria. These patients with intraarticular OO were initially recorded in a table according to anatomical location by a radiologist with 5 years of musculoskeletal imaging experience. A comparison group of the same size (n = 21) with extraarticular OO in a similar or comparable anatomical location, e. g. femoral location or pelvis or shaft of an extremity bone, was recruited to increase comparability. Patients were selected consecutively with the sole criterion of anatomical comparability while satisfying the other inclusion criteria, particularly the availability of a preinterventional MRI examination. The database was searched starting with the most recent date and the first patient with suitable criteria was selected. Subsequent possibly suitable patients were not taken into consideration. In total, n = 21 patients with intraarticular OO and 21 patients with extraarticular OO who underwent CT-guided RFA were included in this study.

Clinical presentation

The local hospital information system (HIS) provided information regarding the clinical presentation at the first visit. This included the patient's pain symptoms prior to RFA. A differentiation was made here between generalized pain and local pain and it was determined whether there was an increase in pain at night or if the pain improved with NSAID intake. Soft-tissue swelling localized around a certain joint was also included in the clinical evaluation prior to RFA. The initial suspected diagnosis was also determined. This included the clinical suspected diagnosis at the time of referral to the orthopedic university hospital based on the clinical examination and the various imaging methods (including ultrasound, X-ray, scintigraphy, and MRI). Radiology reports, documentation of post-treatment (radiological and orthopedic) medical rounds and physician reports regarding outpatient follow-up provided information regarding the clinical course after RFA. This includes the development of pain symptoms and the occurrence of complications.

RFA technique

CT-guided RFA was performed in all patients with intraarticular and extraarticular OO using the same standardized technique [16] [17] [18]. The intervention was performed under sterile conditions and under general anesthesia. Using multidetector CT including multiplanar reconstructions, the access route was initially planned. After administration of local anesthesia (bupivacaine hydrochloride 0.5 %) and skin incision, puncture using a coaxial bone biopsy system (Bonopty^®; AprioMed, Uppsala, Sweden), consisting of a hand drill (length 122 mm, diameter 1.7 mm) and a penetration cannula (length 95 mm, internal diameter 1.8 mm, external diameter 2.1 mm) was performed. After removal of the placeholder, the ablation electrode was inserted through the hollow needle. To position the active tip within the lesion, thin-slice, multiplanar reconstructions were created. Depending on the size of the lesion, two electrode tips (Cool-tip^TM; Valleylab, Tyco Healthcare Group LP, Boulder, CO, USA) of varying length were available (0.7 cm and 1.0 cm). Once the optimal needle position was reached, the cannula was partially retracted to prevent heat propagation along the needle. RFA was then started by slowly increasing the power until the target temperature of 90 °C was reached. The total ablation time for each ablation procedure was always 400 s regardless of the anatomical location. In one patient with intraarticular OO of the distal femur, thermoprotection of the adjacent retropatellar cartilage was performed. The joint space was punctured with a 22G needle and filled with distilled water to create an insulating layer and to increase the distance with respect to the site of maximum heat generation. In general, patients were discharged within 24 hours after post-treatment medical rounds including a physical examination.

MRI technique and protocol

MRI examinations were performed using a 70-cm 3 T whole-body open bore MRI scanner (MAGNETOM Verio, Siemens Healthineers, Erlangen, Germany) equipped with an 18-channel total imaging matrix (Tim [102 × 18] configuration) and various dedicated coils depending on the examined region (e. g. knee coil, flex coil, body coil). All joints were examined using dedicated MRI coils. Each examination followed the same sequence accordingly adapted to the particular examination region. The examination protocol included a T1w sequence without fat saturation, a T2w sequence without fat saturation and a Short-Tau-Inversion-Recovery (STIR) sequence prior to contrast medium (CM) administration and a T1w sequence with and without fat saturation on two planes after CM administration. The T1w sequence without fat saturation was acquired before and after CM administration on the same plane to allow subtraction imaging. MRI examinations performed at a field strength of 1.5 Tesla and with comparable sequences but different sequence parameters (echo time, repetition time) were available in n = 10 patients. Contrast medium was not administered in n = 8 patients.

Image analysis

The image analysis concentrated on a qualitative visual assessment. The presence or absence of effusion/synovitis on MRI was evaluated. In the few cases (n = 8) in which MRI was performed without contrast, synovitis was evaluated in agreement with other work groups [19] [20] based on synovial hypertrophy and concomitant joint effusion. If a contrast-enhanced MRI examination was available, the greater enhancement of the synovialis was used for diagnosis. Moreover, a check for bone marrow edema, soft tissue edema, or a periosteal reaction was performed. A periosteal reaction was defined as T1 and T2 hypointense periosteal thickening or a single layer detached from the cortical bone with or without a T2 hyperintense subperiosteal or paraperiosteal lamella of liquid and corresponding contrast enhancement. In addition, the MRI examinations regarding periosteal reaction were correlated with the preinterventional CT images. Simple continuous or interrupted single-layer periosteal reactions and malignant periosteal reactions, such as spicules, the Codman Triangle, or a sunburst appearance, were differentiated. Detection of the nidus on MRI as well as the contrast enhancement and the signal intensity of the nidus (hypo-, iso-, or hyperintensity compared to the surrounding muscle tissue) were examined as further features. The signal intensity of the nidus on the T2w sequences was then compared to the degree of sclerosis of the nidus on preinterventional CT. The extent of the sclerosis in relation to the total size of the nidus (> 50 % and < 50 %) was evaluated and the density of the nidus (Hounsfield units) was also measured. The evaluation was always performed on the layer with the greatest nidus dimension. If a follow-up examination was available, it was included in the study. All image datasets were available in digital DICOM format on our PACS (image archiving and communication system, GE Centricity EnterpriseTM, Version 4.2.7.4, General Electric Healthcare Pty Ltd. Piscataway, New Jersey, USA) and were evaluated in consensus by two radiologists with 5 and 15 years of musculoskeletal imaging experience.

Statistics

The statistical evaluation was performed using SAS for Windows version 9.4 (SAS Institute Inc., North Carolina). All analyses are descriptive and explorative. Two-sided p-values were reported and a 5 % significance level was set. A descriptive analysis of the demographic and disease-specific information, pretreatment clinical presentation, morphological characteristics and post-treatment response was performed. The following statistical variables were calculated as continuous features: n, mean, standard deviation median, minimum and maximum. Qualitative features were summarized as the absolute and relative frequencies of the individual forms. All features were evaluated for the entire population as well as separately for patients with intraarticular and extraarticular OO. The exact Wilcoxon rank sum test was used to compare age at MRI prior to RFA and the time period of MRI before and after RFA between patients with intraarticular and extraarticular OO. The Chi² test was used to compare the features of the pretreatment clinical presentation and the pretreatment and post-treatment MRI characteristics between patients with intraarticular OO and patients with extraarticular OO. If the requirements for the Chi² test were not met, the Fisher's exact test was used. Frequencies are displayed as grouped bar charts. To evaluate the diagnostic value of effusion/synovitis, bone marrow edema, soft tissue edema, periosteal reaction, contrast enhancement and nidus detection as features to predict intraarticular OO, the sensitivity, specificity, positive and negative predictive value and the exact 95 % confidence intervals were calculated and shown graphically.

Results

Patient group

32 male (76.2 %) and 10 female (23.8 %) patients with an average age of 19.4 years (range: 8.0–55.9 years) were included in the study. An analysis of both the intraarticular OO group and the extraarticular OO group with respect to age and gender showed two very homogeneous patient groups. OO of the femur (n = 18; 42.9 %) and of the humerus (n = 8; 19.0 %) was seen most frequently. The demographic data of the patient groups and the OO location including frequency data are summarized in [Table 1].

Table 1
Patients.
		intraarticular	extraarticular	total
sex	male	16 (76.2 %)	16 (76.2 %)	32
	female	5 (23.8 %)	5 (23.8 %)	10
age (years)	n	21	21	42
	mean	25.2	20.7	23.0
	SD	14.02	8.76	11.77
	median	20.5	18.7	19.4
	min	8.4	8.0	8.0
	max	55.9	36.2	55.9
localization	acetabulum	1 (4.8 %)	1 (4.8 %)	2
	calcaneus	–	1 (4.8 %)	1
	femur	7 (33.3 %)	8 (38.1 %)	15
	glenoid	1 (4.8 %)	–	1
	humerus	4 (19.0 %)	4 (19.0 %)	8
	capitate	1 (4.8 %)	–	1
	cuboid	1 (4.8 %)	–	1
	hamate	1 (4.8 %)	–	1
	metacarpale	–	1 (4.8 %)	1
	sacrum	1 (4.8 %)	1 (4.8 %)	2
	talus	1 (4.8 %)	1 (4.8 %)	2
	tibia	2 (9.5 %)	2 (9.5 %)	4
	ulna	1 (4.8 %)	1 (4.8 %)	2
	phalanx	–	1 (4.8 %)	1

Clinical presentation prior to RFA

An incorrect suspected diagnosis at the time of referral was initially made in n = 14 patients (66.7 %) with intraarticular OO. In contrast, an extraarticular OO was correctly suspected upon initial presentation in 17 patients (81.0 %). Thus, the number of false initial diagnoses in the intraarticular OO group was significantly higher compared to the extraarticular OO control group (p = 0.0018). [Table 2] provides an overview of the different suspected diagnoses and their frequency. All 42 patients complained of local, non-exercise-induced pain prior to treatment. N = 15 patients with intraarticular OO (71.4 %) and n = 18 patients with extraarticular OO (85.7 %) reported pain that increased at night. N = 2 patients (n = 1 intraarticular OO, n = 1 extraarticular OO) did not experience an increase in pain at night. With respect to pain symptoms prior to RFA, there were no significant differences between intraarticular OO and extraarticular OO. A response to NSAIDs was reported in N = 13 patients with intraarticular OO (61.9 %) and n = 14 patients with extraarticular OO (66.7 %). There were also no significant differences between the two patient groups in this regard. In total, n = 5 patients with intraarticular OO additionally presented with soft tissue swelling localized around a specific joint (11.9 %), while this finding was not seen in any patients in the extraarticular OO group (p = 0.0478).

Table 2
Initial diagnosis.
initial diagnosis	intraarticular	extraarticular
osteoidosteoma	7 (33.3 %)	17 (81.0 %)
indistinct tumor mass	3 (14.3 %)	2 (9.5 %)
osteomyelitis	3 (14.3 %)	1 (4.8 %)
malignoma	2 (9.5 %)	–
posttraumatic pain	2 (9.5 %)	–
epicondylitis radialis humeri	1 (4.8 %)	–
meniscal injury	1 (4.8 %)	–
CRMO	1 (4.8 %)	–
enchondroma	–	1 (4.8 %)
chondroblastoma	1 (4.8 %)	–

CRMO = Chronic Recurrent Multifocal Osteomyelitis.

MRI features prior to RFA

The nidus could be identified on MRI in every case regardless of location. [Fig. 1] shows the MRI features prior to RFA and their frequency in the intraarticular and extraarticular OO groups. [Fig. 2] shows the resulting quality criteria of MRI characteristics for evaluating intraarticular OO. While effusion and synovitis were observed in all patients with intraarticular OO ([Fig. 3c, d], [4a, b]), this finding was not seen in anyone in the comparison group. Effusion and synovitis were seen with highly significant greater frequency in the intraarticular OO group (p < 0.0001) and there was perfect sensitivity (100 %) and specificity (100 %) and a higher negative predictive value of 84.6 % with respect to the prediction of intraarticular OO. Both intraarticular and extraarticular OOs showed concomitant bone marrow edema in all cases (100 %). Bone marrow edema is thus extremely sensitive (100 %) with respect to the detection of intraarticular OO but has a lower specificity and lower positive and negative predictive values. If contrast medium was administered for the MRI examination, contrast enhancement of the nidus could always be observed ([Fig. 3b, d], [4b]). In 8 cases (19.0 %), contrast was not administered despite a corresponding recommendation, resulting in a high sensitivity (90 %) and a high negative predictive value (75 %) for this feature regarding intraarticular OO. Perifocal soft tissue edema was observed significantly more frequently in the intraarticular OO group (n = 14 patients (66.7 %)) compared with the extraarticular OO group (n = 6 patients (28.6 %)) (p = 0.0143). However, with a sensitivity of 66.7 % and a specificity of 71.4 %, soft tissue edema is not a good quality criterion for evaluating intraarticular OO. A periosteal reaction was seen on MRI in n = 13 patients (61.9 %) with intraarticular OO and n = 12 patients (57.1 %) with extraarticular OO ([Fig. 3b]). The periosteal reactions could be confirmed in all cases in a correlation with the available preinterventional CT images ([Fig. 4a, c]). In this group only simple continuous single-layer periosteal reactions were seen, while aggressive forms, such as spicules, were not seen. No significant difference between the comparison groups with respect to a periosteal reaction was seen (p = 0.7532). The T1w sequences did not show uniform signal intensity of the nidus (54.8 % hypointense, 35.7 % isointense, 7.1 % hyperintense). The T2 signal of the nidus was also very heterogeneous (16.7 % hypointense, 9.5 % isointense, 73.8 % hyperintense). There was no significant difference regarding signal behavior between intraarticular and extraarticular OO. The correlation of T2w signals with the degree of sclerosis of the nidus on CT showed that all cases of intraarticular and extraarticular OO with sclerosis of the nidus of < 50 % on CT had a hyperintense (93.4 %) or isointense (6.6 %) signal in the T2w sequences. However, in individual OOs with a hyperintense or isointense T2w signal, hypointense segments could be seen in the T2w sequences at sites with focal sclerosis often in the shape of points on CT. In contrast, OOs with sclerosis of the nidus of > 50 % on CT largely showed a hypointense T2w signal (88.9 %). OOs with a hyperintense T2w signal had an average density of 237.4 HU (199–386 HU), while OOs with a hypointense T2w signal had an average density of 528.3 HU (368–787 HU).

Fig. 1 MRI characteristics before RFA.

Fig. 2 Predictive value of MRI characteristics for evaluating Intraarticular Osteoid Osteoma.

Fig. 3 a, b 9-year-old patient with extraarticular osteoid osteoma of the right proximal femur; a Significant bone marrow edema can be seen in the coronal STIR (star). There is no joint effusion. b The nidus shows strong enhancement in the axial T1 post-CM. In addition, the thickened, T1 hypointense periosteum, which is lifted from the cortex, is demarcated by a thin, subperiosteal CM uptake in terms of a periosteal reaction (arrow). You can see reactive CM enhancement in the ventral bordering soft tissue. c, d 13-year-old patient with intraarticular osteoid osteoma of the left proximal femur; c The nidus at the femoral neck can be easily identified in the coronal STIR. In addition to perifocal bone edema (star), there is also obvious joint effusion (open arrow). d In the axial T1 post-CM you can see strong enhancement of the articular capsule like synovitis (open arrow). The nidus shows homogeneous CM uptake.

Fig. 4 17-year-old patient with an intraarticular osteoid osteoma of the left distal femur; a, b MRI before RFA. Bone edema and synovial thickening with joint effusion can be seen in the axial T2fs a (open arrow). The axial T1 post-CM b shows obvious synovial enhancement (open arrow) and CM uptake of the nidus. In both sequences, a hypointense periosteal retraction with subperiosteal fluid accumulation and CM uptake are clearly definable (arrow). c Axial planning CT before RFA. CT-guided RFA was performed with a 7 mm unipolar RFA electrode and a temperature of 90 °C over an ablation time of 6 min. To protect the retropatellar cartilage, the articular cavity was inflated with distilled water. The hypersclerosed periosteum (arrow) is demarcated in correlation to the MRI. d, e MRI 3 months after RFA. The nidus can no longer be clearly identified in the axial T2fs d and axial T1 post-CM e. Joint effusion/synovitis and bone edema are definitely regressive. There is a homogeneously increased T2 signal with correlating CM enhancement in the ablation area (dashed arrow), which is primarily to be seen as post-therapeutic reactive changes.

MRI characteristics after RFA

An MRI scan after RFA was available in a subgroup of n = 31 patients (n = 17 patients with intraarticular OO, n = 14 patients with extraarticular OO). The median time between pretreatment and post-treatment MRI examination was 6.4 months (range: 1.5–25.1 months). In n = 24 patients, contrast medium was administered for the follow-up MRI examination. A decrease in bone marrow edema and in the contrast enhancement of the nidus was always observed after RFA in both the intraarticular OO group and the extraarticular OO group. Effusion/synovitis decreased in all patients with intraarticular OO. Effusion and synovitis were not seen in patients with extraarticular OO even over the course of the disease. If soft tissue edema or a periosteal reaction was present prior to treatment, a decrease after RFA was seen in both the intraarticular OO group and the extraarticular OO group. If these findings were not initially present, they were also not seen over the course of the disease. In summary, all MRI findings decreased after treatment with RFA in both groups. The T1 and T2 signal intensities of the nidus remained highly variable even after RFA and did not differ significantly between intraarticular and extraarticular OO. [Fig. 4] shows an example of a patient from the series with intraarticular OO of the distal femur with the MRI characteristics before and after RFA.

Clinical course after RFA

All patients reported a decrease in pain symptoms after RFA. Complications were not observed in any of the cases. The articular cavity of one patient was filled with distilled water to protect the articular cartilage. No post-treatment cartilage damage occurred.

Discussion

The high rate of false suspected clinical diagnoses in the present study highlights the difficulty of diagnosing intraarticular OO which usually presents with nonspecific symptoms and atypical radiological signs. The literature also includes numerous case descriptions reporting a high frequency of incorrect diagnoses and a treatment delay of 1 to 10 years [21] [22]. In this study the nidus could always be identified on high-resolution MRI resulting in the diagnosis of intraarticular OO. This contradicts the results of previous studies in which the nidus could only be detected on CT not MRI in up to 35 % of cases [23]. This shows the technical development of MRI with respect to image quality and resolution so that reliable identification of the nidus is now possible using the corresponding dedicated examination technique. The most important MRI signs for diagnosing an intraarticular OO are synovitis and joint effusion, which are always present in intraarticular OO and can be differentiated from extraarticular OO with perfect sensitivity and specificity and a high negative predictive value. Effusion and synovitis in intraarticular OO seem to be caused by COX-2 expression of the nidal osteoblasts, resulting in prostaglandin production and thus lymphofollicular inflammation in the perifocal synovial tissue via the arachidonic acid metabolic pathway. [24] [25] [26]. Knowledge of this fundamental morphological difference between intraarticular OO and extraarticular OO is clinically relevant. Intraarticular OO should be included in the differential diagnosis particularly in young patients with joint effusion/synovitis. In these cases a targeted search for the nidus should be performed because it is absolutely necessary for the diagnosis of an OO. In this way the common incorrect diagnoses can be avoided. An intraarticular OO can be practically excluded if signs of synovitis and joint effusion are absent. This means that OO is not necessarily the diagnosis in the case of intraarticular osteolytic bone lesions without synovitis/joint effusion and other differential diagnoses should be primarily considered. This shows that knowledge of the various MRI characteristics is indispensable for radiologists for differentiating intraarticular OO from extraarticular OO and for reliably diagnosing or ruling out intraarticular OO. In the present study and in agreement with previous studies, the nidus was visualized with heterogeneous signal behavior in the T1w and T2w sequences [27]. Differences between intraarticular OO and extraarticular OO were not statistically significant in relation to signal behavior. In a correlation of the T2w signal with preinterventional planning CT examinations, we were able to determine that OOs with > 50 % sclerosis on CT primarily have hypointense T2w signals and significantly higher density values compared to OOs with a hyperintense and isointense T2w signal. Thus, the T2w signal seems to be largely dependent on the extent of calcification. This coincides with the results of Allen et al. [2], which state that signal behavior depends on the degree of sclerosis and on age, size and vascularization. On the whole, T1 and T2 signal intensities are heterogeneous and therefore have limited diagnostic value. The nidus exhibited contrast enhancement in all cases in our study in which contrast was administered. Particularly due to the heterogeneous signal behavior in native T1w/T2w sequences, contrast enhancement of the nidus supports the diagnosis, delimits from other differential diagnoses, such as ganglia, and helps to evaluate relapse in the course of the disease [23] [27] [28] [29]. With a sensitivity of 100 % in both groups, bone marrow edema is perfectly suited for reliably detecting extraarticular as well as intraarticular OO on MRI. If bone marrow edema is not present, an OO can be practically ruled out. However, if bone marrow edema is present, a targeted search for further features of an OO should be performed particularly in young patients. Although perifocal soft tissue edema could be observed more frequently in intraarticular OO, it was not always present. Therefore, it can at best be an indicator of intraarticular OO but cannot reliably differentiate from extraarticular OO due to the low specificity. Simple continuous single-layer periosteal reactions occurred in both groups but cannot be used to differentiate between an intraarticular and extraarticular location of an OO due to the low predictive value. We were able to show that MRI is suitable for identifying an intraarticular OO and for differentiating from an extraarticular OO. MRI can thus prevent delayed diagnosis and allow early treatment. This is particularly important in growing young patients since an intraarticular OO can lead to chronic damage to the articular cartilage and bony deformities [30]. CT-guided RFA is a safe and effective treatment for OO, resulting in a decrease in pathological MRI findings and excellent clinical results [16] [17] [18]. Moreover, promising results regarding high-frequency ultrasound treatment have also been achieved [31]. In the case of an intraarticular OO in a critical location with respect to the articular cartilage, protective measures, e. g. creation of artificial joint effusion, could reduce the risk of post-treatment articular defects. A clear decrease in both pain symptoms and the morphological changes visible on MRI after RFA was also seen in the present study.

Limitations

The present study has a number of limitations to be taken into consideration when formulating possible conclusions. Since this is a retrospective study for which two equal-sized patient groups with similar OO locations were formed to ensure the comparability of MRI characteristics of intraarticular and extraarticular OOs, there could be a selection bias. Randomization could not be performed due to the retrospective nature of the study. A further limitation is the lack of a healthy control group. However, the main goal of this study was to compare intraarticular and extraarticular OOs with respect to their clinical presentation and MRI features. The MRI examinations were performed at different times in the course of the disease so that it is not possible to make any statements as to when certain features occur. A standard examination protocol was not used in all cases and MRI examinations were performed without the administration of contrast medium in n = 8 patients despite a corresponding recommendation. A standard examination protocol would improve the validity of our results. When evaluating synovitis on MRI without contrast, the finding was "no synovitis" if effusion was absent and no synovial thickening could be detected. In these cases, it is theoretically possible that synovitis can only be visualized by contrast enhancement resulting in a false-negative finding. A further limitation of this study is the lack of histological confirmation of OO. However, in consensus with many other work groups, this is not absolutely necessary for diagnosis when the clinical and morphological presentation is typical [15] [16]. The patient group (n = 42 patients) is relatively small but the intraarticular OO group is the largest described to date.

Clinical relevance of the study

The clinical diagnosis of intraarticular OO is often problematic and other differential diagnoses are primarily considered. As a result, correct diagnosis is often delayed, clinical pain symptoms are prolonged and proper treatment is delayed.
MRI is highly suited for diagnosing extraarticular as well as intraarticular OO. Joint effusion and synovitis are always present in intraarticular OO and differentiate between the two types with perfect sensitivity/specificity.
Particularly in young/adolescent patients with joint effusion and typical pain symptoms, intraarticular OO should therefore always be considered. It can be diagnosed based on visualization of the nidus and perifocal bone and soft tissue edema on MRI.
All MRI changes indicating activity, like synovitis, contrast enhancement of the nidus, bone marrow and soft tissue edema, decrease after successful RFA.
The clinical results after RFA are excellent in both forms.

References

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Figures

Fig. 1 MRI characteristics before RFA.

Fig. 2 Predictive value of MRI characteristics for evaluating Intraarticular Osteoid Osteoma.

Fig. 3 a, b 9-year-old patient with extraarticular osteoid osteoma of the right proximal femur; a Significant bone marrow edema can be seen in the coronal STIR (star). There is no joint effusion. b The nidus shows strong enhancement in the axial T1 post-CM. In addition, the thickened, T1 hypointense periosteum, which is lifted from the cortex, is demarcated by a thin, subperiosteal CM uptake in terms of a periosteal reaction (arrow). You can see reactive CM enhancement in the ventral bordering soft tissue. c, d 13-year-old patient with intraarticular osteoid osteoma of the left proximal femur; c The nidus at the femoral neck can be easily identified in the coronal STIR. In addition to perifocal bone edema (star), there is also obvious joint effusion (open arrow). d In the axial T1 post-CM you can see strong enhancement of the articular capsule like synovitis (open arrow). The nidus shows homogeneous CM uptake.

Fig. 4 17-year-old patient with an intraarticular osteoid osteoma of the left distal femur; a, b MRI before RFA. Bone edema and synovial thickening with joint effusion can be seen in the axial T2fs a (open arrow). The axial T1 post-CM b shows obvious synovial enhancement (open arrow) and CM uptake of the nidus. In both sequences, a hypointense periosteal retraction with subperiosteal fluid accumulation and CM uptake are clearly definable (arrow). c Axial planning CT before RFA. CT-guided RFA was performed with a 7 mm unipolar RFA electrode and a temperature of 90 °C over an ablation time of 6 min. To protect the retropatellar cartilage, the articular cavity was inflated with distilled water. The hypersclerosed periosteum (arrow) is demarcated in correlation to the MRI. d, e MRI 3 months after RFA. The nidus can no longer be clearly identified in the axial T2fs d and axial T1 post-CM e. Joint effusion/synovitis and bone edema are definitely regressive. There is a homogeneously increased T2 signal with correlating CM enhancement in the ablation area (dashed arrow), which is primarily to be seen as post-therapeutic reactive changes.

Abb. 1 MR-Charakteristiken vor RFA.

Abb. 2 Gütekriterien der MRT-Charakteristiken zur Evaluation eines intraartikulären Osteoidosteoms.

Abb. 3 a, b 9-jähriger Patient mit extraartikulärem Osteoidosteom am proximalen Femur rechts. a In der koronalen STIR ist ein deutliches Knochenmarködem erkennbar (Stern). Ein Gelenkerguss liegt nicht vor. b Der Nidus zeigt in der axialen T1-post-KM ein starkes Enhancement. Zusätzlich demarkiert sich das verdickte, T1-hypointense und von der Kortikalis abgehobene Periost mit schmaler, subperiostaler KM-Aufnahme im Sinne einer periostalen Reaktion (Pfeil). Ventral sieht man eine reaktive KM-Anreicherung im angrenzenden Weichgewebe. c, d 13-jährige Patientin mit intraartikulärem Osteoidosteom am proximalen Femur links. c Bereits in der koronalen STIR ist der Nidus im Bereich des Schenkelhalses gut identifizierbar. Neben einem perifokalen Knochenödem (Stern) zeigt sich auch ein deutlicher Gelenkerguss (offener Pfeil). d In der axialen T1-post-KM kann man ein kräftiges Enhancement der Gelenkkapsel im Sinne einer Synovitis erkennen (offener Pfeil). Der Nidus nimmt homogen Kontrastmittel auf.

Abb. 4 17-jähriger Patient mit intraartikulärem Osteoidosteom am distalen Femur links. a, b MRT vor RFA. In der axialen T2fs a sind ein Knochenödem und eine Synoviaverdickung mit ausgeprägtem Gelenkerguss zu erkennen (offener Pfeil). In der axialen T1-post-KM b zeigt sich ein deutliches synoviales Enhancement (offener Pfeil) sowie eine Kontrastmittelaufnahme des Nidus. In beiden Sequenzen ist zudem eine hypointense Periostabhebung mit subperiostaler Flüssigkeitsansammlung und KM- Aufnahme gut abgrenzbar (Pfeil). c Axiale Planungs-CT vor RFA. Die CT-gesteuerte RFA erfolgte mit einer 7 mm unipolaren RFA-Elektrode und einer Temperatur von 90 °C über eine Ablationszeit von 6 min. Zur Protektion des retropatellaren Gelenkknorpels wurde die Gelenkhöhle mit destilliertem Wasser gespült. In Korrelation zur MRT demarkiert sich das abgehobene, hypersklerosierte Periost (Pfeil). d, e MRT 3 Monate nach RFA. In der axialen T2fs d und axialen T1-post-KM e lässt sich der Nidus nicht mehr eindeutig identifizieren. Gelenkerguss/Synovitis und Knochenödem sind deutlich rückläufig. Im Ablationsareal zeigt sich eine flächige T2-Signalanhebung mit korrelierender KM-Anreicherung (gestrichelter Pfeil), was in erster Linie als posttherapeutisch-reaktive Veränderungen zu werten ist.